DIGOXIN - IARC Publications Website - Home...Digoxin 383 typically at least 95% (see Section 1.5)....
Transcript of DIGOXIN - IARC Publications Website - Home...Digoxin 383 typically at least 95% (see Section 1.5)....
381
1. Exposure Data
Digoxin is a cardiac glycoside isolated from plants of the genus Digitalis. The use of prepa-rations of cardiac glycoside (synonyms: digi-talis, cardiac steroids) dates back to 1785, when William Withering published his monograph “An account of the foxglove and some of its medical uses” (Withering, 1785; Albrecht & Geiss, 2000). Isolated digoxin has been used since the early 20th century (Cheng & Rybak, 2010).
The Working Group noted that only four of the many digitalis glycosides present in the plant remain important in the marketplace. These are digoxin, digitoxin, β-acetyldigoxin and methyldigoxin (Kleemann, 2012). Furthermore, the term “digitalis use” found in many reports probably refers not to the use of plant mate-rial, which is not commercially available as a medicinal product, but to the use of the isolated compounds. Of the four medicinally available compounds, digoxin is the most important and is exclusively available in some countries, such as the USA (see Section 1.3). The Working Group estimated that digoxin represents at least 90% of the world market for digitalis glycosides.
While use of digitoxin worldwide is much less than that of digoxin, it may be significant in individual countries. Thus, studies reporting use of “digitalis” should be carefully scrutinized since the agent to which people were actually exposed could have been any one of the four digitalis glycosides.
The Working Group noted that most of what has been used under the term “digitalis” in North America and Europe has been digoxin; however, there may be parts of the world where crude extract of the digitalis plant is still in use. No data on the use of digitalis extract were avail-able to the Working Group.
1.1 Chemical and physical data
1.1.1 Nomenclature
Chem. Abstr. Serv. Reg. No.: 20830-75-5 (SciFinder, 2013)Chem. Abstr. Serv. Name: Card-20(22)-enolide, 3-[(O-2,6-dideoxy-β-D-ribo-hexopyranosyl --(1→4)-O-2 ,6-dideoxy-β-D-r ibo-hexo-pyranosyl-(1→4)-2,6-dideoxy-β-D-ribo-hexopyranosyl)oxy]-12,14-dihydroxy-, (3β,5β,12β)- (SciFinder, 2013)IUPAC Systematic Name: 3-[(3S,5R,8R, 9S,10S,12R,13S,14S,17R)-3-[(2R,4S,5S,6R)-5 -[(2 S , 4 S , 5 S , 6 R) -5 -[(2 S , 4 S , 5 S , 6 R) -4 , 5 - d i h y d r o x y- 6 -m e t h y l o x a n -2 -y l ]oxy-4-hydroxy-6-methyloxan-2-yl]oxy-4-hydroxy-6-methyloxan-2-yl]oxy-12,14-dihy-droxy-10,13-dimethyl-1,2,3,4,5,6,7,8,9,11,12,15,16,17-tetradecahydrocyclopenta[a]phenan-thren-17-yl]-2H-furan-5-one (PubChem, 2013)Synonyms: 12β-hydroxydigitoxin
DIGOXIN
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Proprietary names for digoxin: Cardigox; Cardiogoxin; Cardioxin; Cardixin; Cardoxin; Chloroformic digitalin; Coragoxine; Cordioxil; Davoxin; Digacin; Digicor; Digitek; Digomal; Digon; Digosin; Digoxin Nativelle; Dilanacin; Dixina; Dokim; Dynamos; Eudigox; Fargoxin; Grexin; Homolle’s digitalin; Lanacordin; Lanacrist; Lanicor; Lanikor; Lanocardin; Lanorale; Lanoxicaps; Lanoxin; Lanoxin PG; Lenoxicaps; Lenoxin; Longdigox; Mapluxin; NSC 95 100; Natigoxin; NeoDioxanin; Novodigal-Amp.; Purgoxin; Rougoxin; Stillacor; Toloxin; Vanoxin (from SciFinder, 2013).
1.1.2 Structural and molecular formulae and relative molecular mass
From USP (2007)
OO
OO
OO
O
OH
CH3
H
H
H3CH3C H3CH3C
HO
HO HO HO
O
H
H
OH
C41H64O14
Relative molecular mass: 780.94
1.1.3 Chemical and physical properties of the pure substance
Description: Odourless, colourless to white crystals, or white crystalline powder, radi-ally arranged four- and five-sided triclinic plates from dilute alcohol or pyridine (British Pharmacopoeia, 2009; PubChem, 2013)Melting point: Digoxin melts and decomposes between 230 °C and 265 °C (Foss & Benezra, 1980; ChemicalBook, 2013)Density: 1.36 ± 0.1 g/cm3 (temperature, 20 °C; pressure, 760 Torr) (SciFinder, 2013)
Spectroscopy data: Specific optical rotation, ultraviolet, infrared, nuclear magnetic reso-nance, and mass spectral data were reported in the literature (Foss & Benezra, 1980; British Pharmacopoeia, 2009; HSDB, 2013)Solubility: In water, 64.8 mg/L at 25 °C; soluble in dilute alcohol, pyridine, or mixture of chloroform and alcohol; almost insoluble in ether, acetone, ethyl acetate, chloroform; slightly soluble in diluted alcohol, and very slightly soluble in 40% propylene glycol; (PubChem, 2013)Stability data: Digoxin is indefinitely stable when kept in the dark in a tightly closed container. No degradation is noted in tablets after 5 years when stored in tightly closed containers. A solution of digoxin hydrolyses in the presence of acid, yielding digoxigenin bis-digitoxoside, digoxigenin mono-digitox-oside and digoxigenin. A neutral solution in ethanol and propylene glycol is stable for up to 5 years. Digoxin solutions are relatively stable to light, except when stored under intense light for long periods of time (Foss & Benezra, 1980)Storage: Digoxin preparations should be protected from light and stored at 15–25 °C (HSDB, 2013)Octanol/water partition coefficient (log P): 1.26 (HSDB, 2013)Dissociation constant: pKa, basic = −3; pKa, acidic = 7.15 (DrugBank, 2013)Vapour pressure: 3.3 × 10−30 mm Hg at 25 °C (PubChem, 2013)Flash point: 278.5 ± 27.8 °C (SciFinder, 2013)
1.1.4 Technical products and impurities
Since digoxin is isolated from plant materials, at least 21 other cardiac glycosides, including digitoxin, may occur as impurities (British Pharmacopoeia, 2009). The purity of digoxin is
Digoxin
383
typically at least 95% (see Section 1.5). According to the European Pharmacopoeia (2008), not more than 0.5% digitoxin in relation to digoxin may be present as impurity.
(a) Nomenclature for digitoxin
Chem. Abstr. Serv. Reg. No.: 71-63-6 (SciFinder, 2013)Chem. Abstr. Serv. Name: 3β-[(O-2,6-dide-oxy-β-D-ribo-hexopyranosyl-(1→4)-O-2,6-dideoxy-β-D-ribo-hexopyranosyl-(1→4)-2,6-dideoxy-β-D-ribo-hexopyranosyl)oxy]-14-hydroxy-4β,14β-card-20(22)-enolide.Proprietary names for digitoxin: Crystodigin, Digimed, Digimerck.
(b) Structural and molecular formulae and relative molecular mass of digitoxin
OO
OO
OO
O
OH
CH3
H
H
H3CH3C H3CH3C
HO HO
O
H
H
HO
HO
C41H64O13
Relative molecular mass: 764.94
1.2 Analysis
Compendial methods to determine digoxin and digitoxin in pharmaceutical preparations are typically based on liquid chromatography with ultraviolet detection. For detection in human plasma or urine, liquid chromatography with mass spectrometric detection is required to achieve the necessary lower detection limits. The analytical methods are summarized in Table 1.1.
1.3 Production and use
1.3.1 Production
Digoxin is isolated from Digitalis lanata Ehrh., the woolly foxglove, from the Scrophulariaceae family. For the isolation of the therapeutically important secondary glycosides, the finely ground material is moisturized and exposed to glucosidase enzymes at 30–37 °C until glucose is completely removed. Extraction procedures, usually followed by precipitation of tannic acid and related phenolic products with lead salts, afford a crude mixture of cardioactive compounds, which is further purified by chro-matography and/or crystallization. Originally, mixtures of glycosides or crude plant extracts were used in therapy; these have been replaced by chemically pure drugs today, which allow better control of therapy. Total syntheses of cardiac steroids and their corresponding glycosides have been accomplished but are not used commer-cially (Albrecht & Geiss, 2000).
Digitoxin is isolated by extraction of the leaves and seeds of Digitalis purpurea L. (purple foxglove) with 50% ethanol and subsequent treatment with the enzyme digilanidase, which effects cleavage of the β-D-glucose moiety at the chain end of the main glycoside, purpureaglyco-side A (Kleemann, 2012).
β-Acetyldigoxin is prepared from digoxin by acetylation with acetic acid. Methyldigoxin can be prepared by methylation of digoxin, e.g. with dimethyl sulfate (Kleemann, 2012).
1.3.2 Use
(a) Indications
Digoxin and digitoxin are therapeutically the most widely used digitalis glycosides. Table 1.2 lists the most commonly reported clinical indica-tions for digoxin in the USA. While digoxin was once regarded as the drug of choice for conges-tive heart failure with reduced left ventricular
IARC MONOGRAPHS – 108
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Tabl
e 1.
1 A
naly
tica
l met
hods
for d
igox
in
Sam
ple
mat
rix
Sam
ple
prep
arat
ion
Ass
ay m
etho
dD
etec
tion
lim
itR
efer
ence
Com
pend
ial m
etho
dsD
igox
in in
ject
ion,
dig
oxin
Ta
blet
and
dig
oxin
ora
l so
lutio
n
–LC
-UV
C
olum
n: P
acki
ng L
1 M
obile
pha
se: w
ater
and
ace
toni
trile
Fl
ow ra
te: 3
mL/
min
W
avel
engt
h: 2
18 n
m
NR
USP
(200
7)
Dig
oxin
inje
ctio
n, p
aedi
atri
c di
goxi
n in
ject
ion,
pae
diat
ric
digo
xin
oral
solu
tion,
and
di
goxi
n ta
blet
s
–LC
-UV
C
olum
n: C
18
Mob
ile p
hase
: ace
toni
trile
:wat
er (1
0:90
) and
w
ater
:ace
toni
trile
(10:
90)
Flow
rate
: 1.5
mL/
min
W
avel
engt
h : 2
20 n
m
NR
BP (2
009)
Non
-com
pend
ial m
etho
dsH
uman
pla
sma,
rat p
lasm
a an
d ra
t bra
inA
dditi
on o
f DM
A, a
dditi
on o
f NaC
l sa
tura
ted
0.1
mol
/L N
aOH
, col
lect
ion
of
orga
nic
laye
r, ce
ntri
fuga
tion
LC-M
S-M
S C
olum
n: C
18
Mob
ile p
hase
s: am
mon
ium
car
bona
te, a
nd
met
hano
l pH
9.0
Fl
ow ra
te: 0
.7 m
L/m
in
SRM
: 779
.4 m
/z, 6
49.4
m/z
0.1
ng/m
L (L
LOQ
)H
irab
ayas
hi et
al.
(201
1)
Hum
an p
lasm
aD
epro
tein
izat
ion
with
per
chlo
ric
acid
in
wat
er, m
ixin
g an
d ce
ntri
fuga
tion
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: mix
ture
of m
etha
nol a
nd fo
rmic
ac
id in
sodi
um a
ceta
te
Flow
rate
: 1 m
L/m
in
SIM
: 803
.5 m
/z
0.5
ng/m
L (L
LOQ
)V
lase
et a
l. (2
009)
Hum
an b
lood
and
tiss
ues
Mix
ing
with
sodi
um a
ceta
te b
uffer
pH
7, h
omog
eniz
atio
n, c
entr
ifuga
tion,
lo
aded
on
SPE
colu
mn
cond
ition
ed w
ith
met
hano
l, w
ater
, and
sodi
um a
ceta
te
buffe
r, w
ashi
ng w
ith so
dium
ace
tate
bu
ffer,
drie
d un
der v
acuu
m, s
econ
d w
ash
with
20%
isop
ropy
l alc
ohol
, dry
ing,
ad
ditio
n of
ace
tone
, vac
uum
dry
ing,
el
utio
n w
ith a
ceto
ne
LC-E
SI-M
S C
olum
n: C
8 M
obile
pha
se: 0
.1% fo
rmic
aci
d in
a m
ixtu
re o
f 55%
m
etha
nol a
nd 4
5% w
ater
Fl
ow ra
te: 0
.2 m
L/m
in
SIM
: 803
.4 m
/z
0.2
ng/g
(L
LOQ
)Fr
omm
herz
et a
l. (2
008)
Digoxin
385
Sam
ple
mat
rix
Sam
ple
prep
arat
ion
Ass
ay m
etho
dD
etec
tion
lim
itR
efer
ence
Hum
an se
rum
Add
ition
of m
ethy
l ter
t-bu
tyl e
ther
, ce
ntri
fuga
tion,
eva
pora
tion,
and
re
cons
titut
ion
in m
etha
nol
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: 10
mM
am
mon
ium
ace
tate
/0.1%
fo
rmic
aci
d in
wat
er a
nd 0
.1% fo
rmic
aci
d in
ac
eton
itrile
Fl
ow ra
te: 0
.3 m
L/m
in
SRM
tran
sitio
n: 7
98.6
m/z
, 651
.5 m
/z
0.1
ng/m
L (L
LOQ
)Li
et a
l. (2
010)
Hum
an b
lood
Mix
ing
with
am
mon
ium
car
bona
te
buffe
r, ex
trac
tion
(eth
yl a
ceta
te/
hepa
tene
/dic
hlor
omet
hane
= 3
: 1
: 1),
cent
rifu
gatio
n, c
olle
ctio
n of
org
anic
la
yer,
evap
orat
ion,
reco
nstit
utio
n in
ac
eton
itrile
:wat
er
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: 10
mM
am
mon
ium
form
ate
and
acet
onitr
ile
pH 3
.1
Flow
rate
: 0.3
mL/
min
M
RM
tran
sitio
ns: 7
98.4
m/z
, 651
.3 m
/z; 7
98.4
m/z
, 63
3.3
m/z
0.08
ng/
mL
(LLO
Q)
0.03
2 ng
/mL
(LO
D)
Oie
stad
et a
l. (2
009)
Hum
an p
lasm
aM
ixin
g w
ith 1
0% a
mm
oniu
m h
ydro
xide
, ad
ditio
n of
chl
orof
orm
, cen
trifu
gatio
n,
evap
orat
ion,
reco
nstit
utio
n in
1 m
M
trifl
uoro
acet
ic a
cid
and
acet
onitr
ile (7
: 3)
.
LC-E
SI-M
S C
olum
n: U
PLC
® AQ
UIT
Y®
Mob
ile p
hase
: 30%
1m
M a
mm
oniu
m
trifl
uoro
acet
ate
in a
ceto
nitr
ile a
nd 1
00%
wat
er
Flow
rate
: 0.1
mL/
min
SI
M tr
ansit
ion:
780
.94
m/z
, 893
.5 m
/z
0.1
ng/m
L (L
LOQ
)G
rabo
wsk
i et a
l. (2
009)
Hum
an p
lasm
aA
dditi
on o
f con
cent
rate
d N
aOH
an
d m
ethy
l t-b
utyl
eth
er, s
haki
ng,
cent
rifu
gatio
n, e
vapo
ratio
n,
reco
nstit
utio
n in
mob
ile p
hase
LC-E
SI-M
S C
olum
n: C
8 M
obile
pha
se: 0
.25
mM
sodi
um a
ceta
te in
wat
er
and
0.25
mM
sodi
um a
ceta
te in
met
hano
l Fl
ow ra
te: 0
.25
mL/
min
SI
M: 8
03.4
m/z
(pos
itive
mod
e)
0.05
ng/
mL
(LLO
Q)
0.02
5 ng
/mL
(LO
D)
Kir
by et
al.
(200
8)
Hum
an p
lasm
aA
dditi
on o
f buff
er so
lutio
n pH
6.0
, lo
adin
g in
to o
asis
HLB
30 m
g 96
-wel
l pl
ate
prec
ondi
tione
d w
ith m
etha
nol:w
ater
(4
0:60
), el
utio
n of
ana
lyte
with
pur
e m
etha
nol,
evap
orat
ion
and
reco
nstit
utio
n in
met
hano
l
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: 10
mm
ol/L
am
mon
ium
hyd
roge
n ca
rbon
ate/
met
hano
l (1
: 9) a
nd 1
0 m
mol
/L
amm
oniu
m h
ydro
gen
carb
onat
e/m
etha
nol (
9 : 1
) Fl
ow ra
te: 0
.6 m
L/m
in
SRM
tran
sitio
n: 7
98.5
m/z
, 651
m/z
0.04
ng/
mL
(LLO
Q)
Has
him
oto
et a
l. (2
008)
Tabl
e 1.
1 (
cont
inue
d)
IARC MONOGRAPHS – 108
386
Sam
ple
mat
rix
Sam
ple
prep
arat
ion
Ass
ay m
etho
dD
etec
tion
lim
itR
efer
ence
Hum
an p
lasm
a an
d ur
ine
Add
ition
of b
uffer
solu
tion
pH 6
, loa
ding
in
to o
asis
HLB
30 m
g 96
-wel
l pla
te
prec
ondi
tione
d w
ith m
etha
nol:w
ater
(4
0:60
), el
utio
n of
ana
lyte
with
pur
e m
etha
nol,
evap
orat
ion,
reco
nstit
utio
n in
m
etha
nol
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: 5 m
M a
mm
oniu
m a
ceta
te a
nd
acet
onitr
ile
Flow
rate
: 250
μL/
min
SR
M tr
ansit
ion:
798
.5 m
/z, 6
51.4
m/z
(pos
itive
m
ode)
0.2
ng/m
L (L
LOQ
) 1
ng/m
L (L
LOQ
)
Salv
ador
et a
l. (2
006)
Dri
nkin
g-w
ater
, gro
und
wat
er,
surf
ace
wat
er, a
nd w
aste
w
ater
SPE
by u
sing
oas
is H
LB c
artr
idge
LC-M
S-TO
F C
olum
n: C
8 M
obile
pha
se: a
ceto
nitr
ile, w
ater
with
0.1%
form
ic
acid
1–10
00 n
g/L
(LO
D)
Ferr
er &
Th
urm
an (2
012)
Wat
er, s
oil,
sedi
men
t, an
d bi
osol
ids
Extr
actio
n w
ith so
lven
ts, a
nd S
PELC
-MS-
MS
50 n
g/L
in
wat
er (L
OD
)EP
A (2
007)
Plan
t ext
ract
Extr
acte
d fr
om h
erba
ceou
s pla
nts o
f the
ge
nus D
igita
lisLC
-ESI
-MS
Col
umn:
C18
M
obile
pha
se: a
queo
us a
mm
oniu
m fo
rmat
e/m
etha
nol (
40/6
0% v
/v),
pure
met
hano
l Fl
ow ra
te: 0
.3 m
L/m
in
SRM
tran
sitio
n: 7
98.5
m/z
, 780
.4 m
/z
38–9
36 p
g/g
in so
lutio
n (L
OD
)
Jose
phs e
t al.
(201
0)
Rat p
lasm
aA
dditi
on o
f am
mon
ium
chl
orid
e bu
ffer,
acet
onitr
ile a
nd m
ethy
lene
chl
orid
e,
vort
exin
g, c
entr
ifuga
tion,
eva
pora
tion
of
orga
nic
laye
r, re
cons
titut
ion
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: ace
toni
trile
/am
mon
ium
form
ate
Flow
rate
: 0.2
mL/
min
SR
M tr
ansit
ion:
798
.60
m/z
, 651
.6 m
/z
0.1
ng/L
(L
OQ
)Ya
o et
al.
(200
3)
Hum
an se
rum
Incu
batio
n, c
entr
ifuga
tion,
supe
rnat
ant
load
ed in
to a
via
l and
froz
enIC
C
ollo
idal
gol
d m
Ab
prob
e-co
lloid
al g
old
conj
ugat
e w
ith Ig
G
Vis
ual
dete
ctio
n lim
it,
2 ng
/mL
Det
ectio
n tim
e, 2
–5 m
in
Om
idfa
r et a
l. (2
010)
Hum
an b
lood
and
uri
neA
dditi
on o
f wat
er a
nd a
mm
oniu
m a
ceta
te
buffe
r (2
M, p
H 9
.5),
cent
rifu
gatio
n,
colle
ctio
n of
supe
rnat
ant,
clea
n-up
by
SPE
LC-E
SI-M
S C
olum
n: C
18
Mob
ile p
hase
: 20%
ace
toni
trile
in 8
0% 2
mM
am
mon
ium
form
ate
and
80%
ace
toni
trile
in 2
0%
2 m
M a
mm
oniu
m fo
rmat
e Fl
ow ra
te: 0
.2 m
L/m
in
SRM
tran
sitio
n: 7
99.4
m/z
, 651
.4 m
/z
0.05
ng/
mL
(LLO
Q)
Gua
n et
al.
(199
9)
Tabl
e 1.
1 (
cont
inue
d)
Digoxin
387
Sam
ple
mat
rix
Sam
ple
prep
arat
ion
Ass
ay m
etho
dD
etec
tion
lim
itR
efer
ence
Rat i
ntes
tinal
per
fusio
n sa
mpl
esN
RLC
-UV
C
olum
n: C
18
Mob
ile p
hase
: 10
mM
am
mon
ium
ace
tate
, m
etha
nol,
acet
onitr
ile (5
0 : 2
5 : 2
5)
Flow
rate
: 0.5
mL/
min
pH
3.0
W
avel
engt
h: 2
20 n
m
25 n
g/m
L (L
OQ
)Va
rma
et a
l. (2
004)
Hum
an p
lasm
aN
RLC
-ESI
-MS
Col
umn:
C18
M
obile
pha
se: a
ceto
nitr
ile a
nd 2
mM
am
mon
ium
ac
etat
e pH
3.0
Fl
ow ra
te: 0
.2 m
L/m
in
SRM
tran
sitio
n:7
99 m
/z
NR
Trac
qui e
t al.
(199
7)
DM
A, N
,N-d
imet
hyla
ceta
mid
e; IC
, im
mun
ochr
omat
ogra
phy;
IgG
, im
mun
oglo
bulin
G; L
C-E
SI-M
S, li
quid
chr
omat
ogra
phy
elec
tros
pray
ioni
zatio
n m
ass s
pect
rom
etry
; LC
-MS-
MS,
liq
uid
chro
mat
ogra
phy
tand
em m
ass s
pect
rom
etry
; LC
-TO
F-M
S, li
quid
chr
omat
ogra
phy
time
of fl
ight
mas
s spe
ctro
met
ry; L
C-U
V, li
quid
chr
omat
ogra
phy
ultr
avio
let s
pect
rosc
opy;
LL
OQ
, low
er li
mit
of q
uant
ifica
tion;
LO
D, l
imit
of d
etec
tion;
LO
Q, l
imit
of q
uant
ifica
tion;
mA
b, m
onoc
lona
l ant
ibod
y; m
in, m
inut
e; M
RM
, mul
tiple
reac
tion
mon
itori
ng; m
/z, m
ass/
char
ge; N
aCl,
sodi
um c
hlor
ide;
NaO
H, s
odiu
m h
ydro
xide
; NR
, not
repo
rted
; SIM
, sel
ecte
d io
n m
onito
ring
; SPE
, sol
id-p
hase
ext
ract
ion;
SR
M, s
elec
ted
reac
tion
mon
itori
ng
Tabl
e 1.
1 (
cont
inue
d)
IARC MONOGRAPHS – 108
388
ejection fraction and for atrial fibrillation, it has been largely supplanted by other medications (Sleeswijk et al., 2007). Digitoxin is useful for maintenance therapy because its long half-life (5 – 9 days) provides a sustained therapeutic effect even if a dose is missed. For the same reason toxic reactions are not easy to manage. Elimination is independent of renal function (Albrecht & Geiss, 2000).
For congestive heart failure, use of digoxin fails to improve survival (Digitalis Investigation Group, 1997) when compared with placebo, unlike other leading therapies. It does, however, provide symptomatic benefits in some cases and is associated with reduced risk of hospital-ization. USA guidelines suggest its use in situa-tions where recommended therapies (diuretics, angiotensin-converting-enzyme inhibitors and β-blockers) fail to produce adequate symptom relief (Hunt et al., 2009). European guidelines continue to recommend digoxin as one of several therapies used in combination for the manage-ment of congestive heart failure (Dickstein et al., 2008).
As for congestive heart failure, use of digoxin for atrial fibrillation has also declined
in preference for other medications, particu-larly β-blockers and non-dihydropyridine calcium-channel blockers. Digoxin is generally less effective than other drugs in producing consistent reduction of heart rate, particularly during exertion (McNamara et al., 2003). Joint USA/European Union guidelines recommend against use of digoxin as a first-line agent in most cases of atrial fibrillation (Fuster et al., 2006).
(b) Dosage
Administration is typically oral, although preparations for intravenous administration exist. Typically, digoxin is used orally for months to years, while intravenous use requires careful medical monitoring and is given only in the short-term. The absorption ratio was found to be 70%, the decay ratio is 20%, the effective dose level is 2 mg, and the maintenance dose is 0.5 mg (Albrecht & Geiss, 2000).
For the treatment of heart failure, atrial fibril-lation, the loading-dose regimen for intravenous administration is a single dose of 0.4–0.6 mg, with additional doses of 0.1–0.3 mg every 6–8 hours to be given with caution until there is clinical evidence of adequate effect, and the
Table 1.2 Most commonly reported clinical indications for digoxin in the USA, 2011–2012
Diagnosis ICD-9 codea Drug uses (in 1000s)
Percentage of total
Atrial fibrillation 427.301 1595 42.3Hypertensive heart disease, other 402.901 621 16.5Congestive heart failure 428.001 501 13.3Other primary cardiomyopathy, NOS 425.402 113 3.0Chronic ischaemic disease, unspecified 414.901 81 2.1Essential hypertension, NOS 401.901 65 1.7Surgery after heart disease treatment V67.038 53 1.4Medical follow-up after atherosclerotic heart disease V67.533 50 1.3Paroxysmal supraventricular tachycardia 427.001 50 1.3Chronic ischaemic disease, unspecified, with hypertension 414.501 50 1.3All other diagnoses – 593 15.7Total with reported diagnoses – 3771 100.0
a ICD-9 codes are a more detailed, proprietary version developed by IMS Health.Prepared by the Working Group on the basis of data from IMS Health (2012b)ICD-9, International Classification of Diseases Revision Nine; NOS, not otherwise specified
Digoxin
389
total dose should not exceed 0.008–0.015 mg/kg bw. The oral dosage for this indication is a single dose of 0.5–0.75 mg, then additional doses of 0.125–0.375 mg may be given cautiously every 6–8 hours until clinical evidence of adequate effect, up to a total dose of 0.75–1.25 mg (for a patient weighing 70 kg). The maintenance dose is 0.125–0.5 mg/day, intravenous or oral (Medscape (2013).
Most generic tablet preparations of digoxin average 70–80% oral bioavailability, with 90–100% oral bioavailability for digoxin elixir and the encapsulated gel preparation. Parenteral digoxin is available for intravenous administra-tion, and is of value in patients who are unable to take oral formulations. Caution to avoid over-dosing is necessary in elderly patients or those with renal impairment (Li-Saw-Hee & Lip, 1998). In general, the therapeutic index for digoxin is narrow (Ehle et al., 2011).
When digoxin is indicated, suggested thera-peutic ranges of serum concentrations of digoxin are lower now than in the past (Hunt et al., 2009), particularly given the report that mortality among digoxin users was associated with higher serum concentrations of this drug (Rathore et al., 2003). In a study of post-mortem cases, the range of serum digoxin concentrations in cases of over-dose was 2.7–6.8 nmol/L (mean, 4.7 nmol/L) [2.1–5.3 ng/L (mean, 3.7 ng/L)] (Eriksson et al., 1984).
Country-dependent differences in formula-tions may be correlated to the range of available tablet strengths. For example, the dosage was significantly higher in some hospitals in the USA and France than in the United Kingdom, and significantly higher in France than in the USA (Saunders et al., 1997).
(c) Trends in use
Use of digoxin in the USA has declined substantially for treatment of congestive heart failure (Banerjee & Stafford, 2010) and of atrial fibrillation (Stafford et al., 1998; Fang et al.,
2004). Trends in the European Union may have lagged behind those in the USA, but use for both conditions has declined (Sturm et al., 2007). Use of digoxin may have been reduced between 1991 and 2004 in the USA, but not in the United Kingdom (Haynes et al., 2008).
The Food and Drug Administration (FDA) reported that digitoxin and acetyldigitoxin are no longer manufactured in the USA (FDA, 2013).
Globally, there are 160 licensed products containing digoxin, while there are only seven licensed products containing digitoxin in Germany, Austria, Hungary, and Norway (Index Nominum, 2013).
Despite the introduction of new therapeutic strategies, cardiac glycosides are still widely used, and digoxin belongs to the 10 most frequently prescribed drugs in the USA (Albrecht & Geiss, 2000). In Estonia, the consumption of digoxin was very high in the times of the former Soviet Union and decreased in the first years of inde-pendence. When problems with drug availability were overcome, the use of digoxin increased by 35% in 1994–97 (Pähkla et al., 1999).
While a rare event, the homicidal use of digoxin has been described. Suicide by digoxin may have been more frequent in continental Europe, but has also occurred in the USA and England (Burchell, 1983).
Total worldwide sales of digoxin were US$ 142 million in 2012, with 33% occurring in the USA (US$ 47 million). Other nations reporting appreciable use of digoxin included Japan (US$ 14 million), Canada (US$ 11 million), and the United Kingdom (US$ 9 million) (IMS Health, 2012a).
In the USA in 2012, digoxin was reported by office-based physicians in 1.85 million drug uses, and was being taken by approximately 700 000 patients (IMS Health, 2012b). The trend in use of digoxin in the USA is shown in Fig. 1.1. According to the IMS Health National Prescription Audit Plus, there were a total of 9.6 million prescriptions
IARC MONOGRAPHS – 108
390
for digoxin in 2012, down from 14.6 million prescriptions in 2008 (IMS Health, 2012c).
1.4 Occurrence and exposure
1.4.1 Natural occurrence
The principal natural occurrence of digoxin is in the leaves of Digitalis lanata Ehrh., but it may also occur in some other Digitalis species (Hollman, 1985). After leaf-tissue damage or plant harvest, the primary glycoside lanatoside C is converted to the secondary glycoside digoxin by the endogenous enzyme, digilanidase, present in the leaves, and by subsequent deacetylation. D. lanata leaves were found to contain digoxin at 8.6–13.2 µg/100 mg and its precursor, lanatoside C, at 55.8–153.2 µg/100 mg, depending on the health of the plant material (Pellati et al., 2009). Environmental factors that influence the digoxin content in D. lanata are carbon-dioxide enrich-ment and water stress (Stuhlfauth et al., 1987).
1.4.2 Occupational exposure
No data were available to the Working Group.
1.5 Regulations and guidelines
Digoxin has been assigned classification as a “water hazard” in Germany and as an “environ-mental hazard” in several USA states (SciFinder (2013). The United States Environmental Protection Agency (EPA) assigned it to the list of “extremely hazardous substances” mandated by Section 302 of the Emergency Planning and Community Right-to-Know Act of 1986 (EPCRA), for which the reportable quantity is 10 lbs [~4.5 kg] and the threshold planning quantity is 10/10 000 lbs [4.5/4536 kg].
Digoxin is specified in several official phar-macopoeias (Table 1.3).
2. Cancer in Humans
Beginning in the late 1970s, several small studies based on case series or chart reviews reported a lower risk of cancer of the breast in women using “digitalis” (see introduction to Section 1) (Stenkvist et al., 1979, 1982; Goldin & Safa, 1984). These reports, mostly in brief corre-spondence, have been cited as supporting the consideration of digitalis as a possible therapy for cancer of the breast (Stenkvist, 1999; Haux, 1999); however, because so little information was provided and larger studies with stronger designs were available, these early studies were judged to be uninformative and were not consid-ered further.
The studies reviewed by the Working Group included a measure of relative risk, such as odds ratios, hazard ratios, and incidence rate ratios. Varied designs were used in these studies. Some studies evaluated associations between risks of cancers of all types and exposures to a wide range of pharmaceuticals, or to a more restricted range of cardiovascular drugs. Others examined risk factors for specific cancers, typically including prescription drugs together with evaluation of other demographic and health parameters. In recent years, national registries of prescription drug use have yielded large data sets in which follow-up can be linked to cancer outcomes in cohort studies.
Many reports described only “digitalis” exposure, and therefore may refer to either digoxin (much more commonly used, especially in recent years) or digitoxin. Even when some epidemiological studies specified “digoxin,” the subjects who were enrolled during years when digitoxin was more widely used might have also used digitoxin (e.g. because of renal failure). The studies describing “digitalis” use are therefore included, with the exposure type digoxin, digi-toxin, or digitalis, indicated in the tables. Most
Digoxin
391
of what has been used under the term “digitalis” in North America and Europe has been digoxin.
2.1 Cancer of the breast
2.1.1 Case–control studies
See Table 2.1Studies of the association of risk of cancer
with use of digoxin and related drugs have focused mainly on cancer of the breast. Aromaa et al. (1976) reported a register-based case–control study in which use of “digitalis” (and many other cardiovascular drugs) in the year before diagnosis was compared in 109 hyper-tensive women with cancer of the breast and in 109 matched hypertensive women without cancer of the breast. Hypertensive women with cancer of the breast were more likely to be using
digitalis than were women without cancer of the breast (relative risk, RR, 2.67; 95% CI, 0.99–8.33; in the subset restricted to 65 pairs with similar follow-up time.). [Both cases and controls were hypertensive and both were therefore at a high risk of cardiovascular disease. This compara-bility enhanced internal validity, but it may have reduced generalizability.]
Lenfant-Pejovic et al. (1990) described risk factors for cancer of the breast in men in France and Switzerland, comparing 91 cases with 255 controls recruited from hospital cancer clinics in France and a cancer registry in Switzerland, and matched for age and area of residence. Data on risk factors were limited to information available in physician interviews by mail or telephone, and clinical record reviews. Of all prescribed drugs, only use of digitalis for at least 3 months before
Fig. 1.1 Trends in use of digoxin as a drug in the USA
0
300
600
900
1200
1500
2004 2005 2006 2007 2008 2009 2010 2011 2012
Qua
rter
ly d
rug
uses
(th
ousa
nds)
Year
Prepared by the Working Group on the basis of data from IMS Health National Disease and Therapeutic Index, 2004–12 (IMS Health, 2012b).
IARC MONOGRAPHS – 108
392
Tabl
e 1.
3 Re
gula
tion
s in
pha
rmac
opoe
ial m
onog
raph
s on
dig
oxin
Reg
ulat
ion
WH
O In
tern
atio
nal P
harm
acop
oeia
, 4t
h ed
itio
nU
nite
d St
ates
Ph
arm
acop
eial
C
onve
ntio
n 30
Euro
pean
Pha
rmac
opoe
ia 7
.0Ja
pane
se P
harm
acop
oeia
XV
I
Con
tent
C41
H64
O14
(d
ried
subs
tanc
e)95
.0–1
03.0
%95
.0–1
01.0
%96
.0–1
02.0
%96
.0–1
06.0
%
Iden
tity
test
sTe
sts A
BD o
r BC
D m
ay b
e ap
plie
d:
A. I
R B.
TLC
C
. Col
our r
eact
ion
with
din
itrob
enze
ne/
etha
nol
D. C
olou
r rea
ctio
n w
ith fe
rric
chl
orid
e/gl
acia
l ace
tic a
cid/
sulfu
ric
acid
A. I
R B.
HPL
C
C. T
LC
IR1.
Col
our r
eact
ion
with
ferr
ic
chlo
ride
hex
ahyd
rate
/ace
tic a
cid/
sulfu
ric
acid
2.
IR
Spec
ific
optic
al
rota
tion
+13.
6° to
+14
.2° (
0.10
g/m
L in
pyr
idin
e)–
+13.
9° to
15.
9° (0
.50
g in
25
mL
met
hano
l/met
hyle
ne c
hlor
ide
50 :
50)
+10.
0 to
+ 1
3.0°
(0
.20
g in
10
mL
pyri
dine
)
Sulfa
ted
ash
Max
. 1.0
mg/
g–
Max
. 0.1%
–Lo
ss o
n dr
ying
Max
. 10
mg/
gM
ax. 1
.0%
Max
. 1.0
%M
ax. 1
.0%
Resid
ue o
n ig
nitio
n–
Max
. 0.5
%–
Max
. 0.5
%G
itoxi
nA
bsor
banc
e at
352
nm
, max
. 0.2
2 (a
bout
40
mg/
g)–
––
Rela
ted
subs
tanc
es/
puri
tyTL
C te
st, a
bsen
ce o
f spo
ts th
at a
re
mor
e in
tens
e th
an st
anda
rd so
lutio
n at
0.
25 m
g/m
L
TLC
test
, no
spot
that
is
mor
e in
tens
ive
than
gi
toxi
n st
anda
rd so
lutio
n (n
ot m
ore
than
3%
of
any
rela
ted
glyc
osid
e as
gi
toxi
n)
HPL
C: s
peci
fic li
mits
for a
bout
12
rela
ted
subs
tanc
es a
re
spec
ified
HPL
C: t
otal
are
a of
pea
ks o
f im
puri
ties i
s max
. 3%
Org
anic
vol
atile
im
puri
ties
–G
ener
al re
quir
emen
ts,
exce
pt li
mits
for m
ethy
lene
ch
lori
de a
nd c
hlor
ofor
m
are
2000
µg/
g
––
Bact
eria
l en
doto
xins
Max
. 200
.0 IU
of e
ndot
oxin
per
mg
––
–
HPL
C, h
igh-
perf
orm
ance
liqu
id c
hrom
atog
raph
y; IR
, inf
rare
d; IU
, int
erna
tiona
l uni
ts; T
LC, t
hin-
laye
r chr
omat
ogra
phy
Ada
pted
from
The
Uni
ted
Stat
es P
harm
acop
oeia
l Con
vent
ion
(200
6), E
urop
ean
Phar
mac
opoe
ia (2
008)
, The
Inte
rnat
iona
l Pha
rmac
opoe
ia (2
011)
, Pha
rmac
eutic
als a
nd M
edic
al D
evic
es
Age
ncy
(201
1)
Digoxin
393
diagnosis was associated with increased risk (11 users among cases; odds ratio, OR, 4.1; 95% CI, 1.4–12.4). [The data from France and Switzerland were collected in different ways and the Working Group questioned the quality of the data obtained from medical records and physician interviews.]
In another study of risk factors for cancer of the breast in men, Ewertz et al. (2001) compared 156 incident cases in men in Norway, Sweden, and Denmark with 468 men matched for year of birth, and country. Many variables were eval-uated using self-administered questionnaires, including use of prescribed drugs. Among all drugs assessed, digoxin stood out most strongly, with odds ratios for digoxin of 1.8 (95% CI, 0.7–4.4) in men with < 5 years use and 2.0 (0.9–4.4) for ≥ 5 years use. After adjustment for body mass index determined from self-estimated weight and height 10 years before diagnosis, the association between cancer of the breast and digoxin use was still 1.8 (P = 0.08). [Recalculated by the Working Group from observed/expected data to be 1.9 (95% CI, 1.05–3.48).]
Ahern et al. (2008) identified 5565 postmeno-pausal women with incident cancer of the breast who used digoxin with a 10 : 1 birth year- and resi-dence area-matched population-control group in Denmark in 1991–2007. Use of digoxin was ascertained by county-level prescription registry data, and by design, all subjects were required to have used digoxin for ≥ 2 years before diagnosis (and use was likely to be current). Adjustments included age, past use of hormone replacement therapy, nonsteroidal anti-inflammatory drugs (NSAIDs), and anticoagulants including aspirin. Among the cases of cancer of the breast, 324 used digoxin compared with 2546 controls, yielding an adjusted odds ratio of 1.30 (95% CI, 1.14–1.48). Relative to non-users, the odds ratios increased with duration of use from 1.25 (95% CI, 1.03–1.52) with 1–3 years of use to 1.30 (95% CI, 1.05–1.61) with 4–6 years of use to 1.39 (95% CI, 1.10–1.74) with > 6 years of use. The findings persisted after adjustment for exposure to estrogen, use of other
drugs, confounding by indication, and frequency of mammography. [This large study was regarded as being of high quality. However, the Working Group noted that some important risk factors of cancer of the breast, notably parity, obesity, and alcohol drinking, were not controlled in the analysis.]
2.1.2 Cohort studies
See Table 2.2Using data from persons enrolled in the
Kaiser Permanente Medical Care Programme, Friedman & Ury (1980) linked prescription-drug use for 95 drugs and drug classes between 1969 and 1973 to subsequent cancer outcomes (56 types) registered within this health-care system until 1976. The drugs evaluated included “digi-talis” as a group. A more detailed presentation of digitalis-related associations used cancer-out-come data for 143 594 subjects updated to 1980 (Friedman, 1984) (results provided in Table 2.2). The age–sex standardized morbidity ratio for cancer of the breast and ever-use of digitalis was 1.2 [95% CI, 0.74–1.87]. [This study was large and was able to examine the association of cancer with many different drugs; however, the preci-sion of specific drug–cancer associations was limited and there was some concern about the large number of comparisons.]
Haux et al. (2001) used a database of plasma concentrations of digitoxin for 9271 women and men in Trondheim, Norway, who were undergoing their first treatment with digitoxin between 1986 and 1996. The risk of developing cancer in people receiving their first treatment with digitoxin was compared with the incidence of cancers with at least 30 expected cases (all sites, breast, prostrate, colorectum, lung, kidney/urinary, melanoma, lymphoid/leukaemia) in the national population. Standardized incidence ratios (SIR) for most cancers, including cancer of the breast, were higher (typically by about 25%) among digitoxin users. In an analysis of cancer
IARC MONOGRAPHS – 108
394
Tabl
e 2.
1 Ca
se–c
ontr
ol s
tudi
es o
n us
e of
dig
oxin
and
can
cer o
f the
bre
ast
Ref
eren
ce,
stud
y lo
cati
on a
nd
peri
od
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
Expo
sed
case
sEx
posu
re
cate
gory
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
fo
r pot
enti
al
conf
ound
ers
Com
men
ts
Aro
maa
et
al.
(197
6),
Finl
and,
ca
ses
repo
rted
in
1973
Wom
en w
ith
brea
st c
ance
rs a
nd
hype
rten
sion
(n =
10
9) c
ompa
red
with
m
atch
ed w
omen
with
hy
pert
ensio
n on
ly
(n =
109
)
Pres
crip
tion-
acqu
ired
ca
rdio
vasc
ular
dr
ugs
Brea
st28
Any
dig
italis
us
e vs
no
use
1.33
(0.7
3–2.
48)
Age
, ge
ogra
phic
al
area
Dig
italis
use
was
a
seco
ndar
y ou
tcom
e,
but t
he st
rong
est
asso
ciat
ion
seen
am
ong
pres
crip
tion
drug
use
d; p
roba
bly
incl
uded
som
e di
gito
xin
user
s.
16
Any
dig
italis
us
e vs
no
use
(cas
e–co
ntro
l pa
irs w
ith
com
para
ble
trea
tmen
t du
ratio
n)
2.67
(0.9
9–8.
33)
Lenf
ant-
Pejo
vic
et a
l. (1
990)
, Sw
itzer
land
, 19
70–8
6,
and
Fran
ce,
1975
–88
Men
with
bre
ast
canc
er (n
= 9
1)
iden
tified
in
hosp
ital o
r by
tum
our r
egis
trie
s co
mpa
red
with
men
w
ith c
olor
ecta
l, ha
emat
olym
phat
ic, o
r sk
in c
ance
rs (n
= 2
55)
Hos
pita
l cha
rt
abst
ract
s and
ph
ysic
ian
inte
rvie
w; d
igita
lis
spec
ified
Brea
st,
aden
o-ca
rcin
oma
11A
ny d
igita
lis
use
vs n
o us
e4.
1 (1
.4–1
2.4)
Con
trol
s m
atch
ed
by a
ge a
nd
hosp
ital
Dig
italis
was
the
only
one
of m
any
ther
apeu
tic d
rugs
for
whi
ch a
n as
soci
atio
n w
as fo
und.
Pro
babl
y in
clud
ed so
me
digi
toxi
n us
ers.
Ewer
tz et
al.
(200
1),
Nor
way
, Sw
eden
, D
enm
ark,
19
87–9
1
Men
with
bre
ast
canc
er (n
= 1
56)
com
pare
d w
ith m
en
in p
opul
atio
n re
gist
ry
(n =
468
)
Self-
repo
rted
qu
estio
nnai
res
incl
udin
g pr
escr
iptio
n-dr
ug
use
and
othe
r de
mog
raph
ic a
nd
heal
th d
ata
Brea
st20
Nev
er d
igox
in1.
0 (r
ef.)
Mat
ched
fo
r sex
, ag
e; o
vera
ll an
alys
is
adju
sted
for
BMI
Mul
tiple
com
pari
sons
to
div
erse
de
mog
raph
ic,
heal
th, a
nd d
rug-
use
vari
able
s, bu
t as
soci
atio
n fo
r dig
oxin
ap
pear
ed to
be
the
stro
nges
t am
ong
drug
s; pr
obab
ly
incl
uded
som
e di
gito
xin
user
s. P
= 0.
08 fo
r ove
rall
asso
ciat
ion
betw
een
digo
xin
use
and
brea
st
canc
er
Dig
oxin
< 5
yr
1.8
(0.7
–4.4
)D
igox
in ≥
5 y
r2.
0 (0
.9–4
.4).
Digoxin
395
Ref
eren
ce,
stud
y lo
cati
on a
nd
peri
od
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
Expo
sed
case
sEx
posu
re
cate
gory
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
fo
r pot
enti
al
conf
ound
ers
Com
men
ts
Ahe
rn et
al.
(200
8),
Nor
th
Jutla
nd
and
Aar
hus
Cou
ntie
s, D
enm
ark,
19
91–2
007
Post
men
opau
sal
wom
en w
ith b
reas
t ca
ncer
(n =
556
5)
com
pare
d w
ith
mat
ched
wom
en fr
om
popu
latio
n re
gist
ry (n
=
55 6
50)
Cou
nty-
base
d ph
arm
acy
regi
stri
es
Brea
st52
41N
ever
-use
r1.
0 (r
ef.)
Age
, loc
atio
n;
use
of a
nti-
infla
mm
ator
y dr
ugs,
antic
oagu
lant
s or
HRT
Tum
our E
R st
atus
not
ex
amin
ed. A
ssoc
iatio
n no
t gre
atly
cha
nged
by
adj
ustm
ents
; Su
gges
tion
of
incr
ease
d ri
sk w
ith
long
er d
urat
ion
of u
se.
May
hav
e in
clud
ed
som
e di
gito
xin
user
s in
early
yea
rs,
alth
ough
des
crib
ed a
s di
goxi
n us
ers.
Adj
uste
d fo
r age
, co
unty
of r
esid
ence
, an
d pa
st re
ceip
t of
HRT
, ant
icoa
gula
nts,
high
- and
low
-dos
e as
piri
n, a
nd N
SAID
s.
324
Ever
use
d di
goxi
n (r
estr
icte
d to
ca
se–c
ontr
ol
pair
s with
co
mpa
rabl
e tr
eatm
ent
dura
tion)
1.30
(1.14
–1.4
8)
128
1–3
yr1.
25 (1
.03–
1.52
)10
34–
6 yr
1.30
(1.0
5–1.
61)
937–
18 y
r1.
39 (1
.10–
1.74
)
BMI,
body
mas
s ind
ex; E
R, e
stro
gen
rece
ptor
; HRT
, hor
mon
e re
plac
emen
t the
rapy
; NSA
IDs;
non-
ster
oida
l ant
i-infl
amm
ator
y dr
ugs;
ref.,
refe
renc
e; v
s, ve
rsus
; yr,
year
Tabl
e 2.
1 (
cont
inue
d)
IARC MONOGRAPHS – 108
396
incidence in people before their first use of digi-toxin, odds ratios for most cancers were similarly increased. An analysis of the relationship between risk of cancer and serum concentration of digi-toxin did not show a coherent relationship for cancer of the breast. [The Working Group noted that the national population used as comparison group was external to the study population and may differ in its underlying disease risk or in the quality of cancer ascertainment. Elevated risk of cancer in the study population before begin-ning treatment may be attributable to under-lying increases in the frequency of common risk factors for cancer and for cardiovascular disease requiring digitoxin, rather than the use of digi-toxin itself. In addition, estimates of digitoxin dose were based on a single measurement at the start of treatment and there was no information about ongoing exposure.]
Biggar et al. (2011) reported a nationwide cohort study in Denmark, evaluating incidence of cancer of the breast in women prescribed digoxin. Data were obtained by linking the national Danish prescription-drug database (available since 1995) and the nationwide Danish cancer registry until 2008. Among 104 648 women using digoxin, 2144 developed cancer of the breast. Risks associated with current and former use, and duration of current use among new users only were analysed, with incidence rate ratios for cancer of the breast adjusted for attained age at diagnosis and calendar year. The relative risk (RR) for current use was 1.39 (95% CI, 1.32–1.46), with higher risk for devel-oping estrogen receptor-positive tumours (RR, 1.35; 95% CI, 1.26–1.45) than estrogen receptor-negative tumours (RR, 1.20; 95% CI, 1.03–1.40) among digoxin users. Incidence was not increased in women who had used digoxin in the past (SIR, 0.91; 95% CI, 0.83–1.00). Increased incidence was not associated with duration of use, but declined to baseline within 1 year after use of digoxin had ceased. [This was regarded as a high-quality study, with the capacity to
examine risk by estrogen-receptor status being a particular strength. The study did not examine the effect of menopausal status; however, most women included were postmenopausal (median age, 79 years). Information on other covariates was limited. While there are many risk factors for cancer of the breast, the inability to control for alcohol drinking and obesity was likely to be of greatest concern.]
Biggar et al. (2013) examined features of cancer of the breast in a case–case comparison of cancers developed in 369 women who were using digoxin at the time of diagnosis with 34 085 cancers in women not using digoxin. Tumours in users were significantly more likely (P = 0.002) to be estrogen receptor-positive (85%) than estrogen receptor-negative (79%), and to have low versus high histological grades, features suggesting better prognosis. [The prognostic factors for cancer of the breast in women receiving digoxin and in women receiving estrogen were similar and more favourable, e.g. estrogen receptor-posi-tive tumours, than in women not receiving treat-ment (IARC, 2012).]
2.2 Cancers of the uterus and ovary
Cohort study
See Table 2.3In a cohort study in Denmark, Biggar et al.
(2012) evaluated the risk of cancer of the uterus. The methods and data sources were identical to those in the study of cancer of the breast described in Section 2.1.2 (Biggar et al., 2011). As with cancer of the breast, the incidence of cancer of the uterus (n = 461 cases in digoxin users) was increased among current users (RR, 1.48; 95% CI, 1.32–1.65). In addition, this study also evaluated cancers of the ovary (n = 277) and cervix (n = 117) as “control cancers,” finding no increase in the incidence of either cancer (RR for cancer of the ovary, 1.06; 95% CI, 0.92–1.22; RR for cancer of the cervix, 1.00; 95% CI, 0.79–1.25)
Digoxin
397
Tabl
e 2.
2 Co
hort
stu
dies
on
use
of d
igox
in a
nd c
ance
r of t
he b
reas
t
Ref
eren
ce,
loca
tion
, and
pe
riod
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
Expo
sed
case
sEx
posu
re
cate
gory
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
for p
oten
tial
con
foun
ders
C
omm
ents
Frie
dman
(1
984)
, Kai
ser
Perm
anen
te
Med
ical
Car
e Pr
ogra
m (U
SA),
1969
–80
Mem
bers
of a
pr
ivat
e he
alth
-ca
re in
sura
nce
prog
ram
me
(n =
143
594
)
Phar
mac
y da
taba
se fr
om
Hea
lth P
lan
Lung
48D
igita
lis
ever
-use
(d
igox
in,
digi
toxi
n,
digi
talis
)
1.7
[1.2
2–2.
20]
Age
, sex
M
ain
sum
mar
y fo
r all
drug
-can
cer
rela
tions
hips
repo
rted
by
Frie
dman
&
Ury
(198
0). U
pdat
ed to
198
0: F
ried
man
(1
984)
. Mul
tiple
com
pari
sons
. N
o as
soci
atio
n fo
und
for o
ther
can
cers
.
Col
on35
1.5
[1.0
2–2.
04]
Brea
st20
1.2
[0.7
4–1.
87]
Pros
tate
341.
4 [1
.00–
2.01
]
Hau
x et
al.
(200
1),
Tron
dhei
m,
Nor
way
, 19
86–9
6
Peop
le
(n =
9 2
71)
unde
rgoi
ng
thei
r firs
t di
gito
xin
trea
tmen
t
Dig
itoxi
n in
pla
sma
mea
sure
d in
a c
entr
al
labo
rato
ry
All
sites
641
Dig
itoxi
n us
e1.
27 (1
.18–1
.37)
Age
, yea
r of b
irth
, sex
In
cide
nce
com
pare
d to
pop
ulat
ion
inci
denc
e w
hen
> 30
cas
es w
ere
expe
cted
U
se b
ased
on
sing
le a
sses
smen
t of
digi
toxi
n. A
hig
h ri
sk o
f can
cer
diag
nose
d be
fore
dig
itoxi
n m
easu
rem
ent (
not s
how
n) su
gges
ted
high
can
cer r
isk
prec
eded
use
. Exp
ecte
d nu
mbe
rs o
f can
cers
obt
aine
d fr
om
natio
nal r
egis
try
rate
s.
Fem
ale
brea
st57
1.25
(0.9
5–1.
62)
Pros
tate
108
1.25
(1.0
3–1.
50)
Col
orec
tum
127
1.29
(1.0
6–1.
51)
Lung
631.
35 (1
.04–
1.74
)
Kid
ney/
urin
ary
591.
14 (0
.87–
1.47
)M
elan
oma
611.
23 (0
.94–
1.58
)Le
ukae
mia
/ly
mph
oma
(C81
–C
85/C
88/9
2)
531.
41 (1
.06–
1.85
)
Brea
stD
igito
xin
conc
entr
atio
n (n
g/m
L):
< 16
1.00
(ref
.)D
ose–
resp
onse
on
the
coho
rt o
n di
gito
xin
user
s by
diffe
rent
leve
ls of
di
gito
xin
plas
ma
conc
entr
atio
n at
firs
t m
easu
rem
ent d
ivid
ed in
tert
iles
16–2
21.
04 (0
.59–
1.84
)>
220.
90 (0
.48–
1.67
)
Bigg
ar et
al.
(201
1),
Den
mar
k,
1995
–200
8
Wom
en
aged
≥ 2
0 yr
(n
= 2
011
381
)
Nat
ionw
ide
phar
mac
y re
gist
ry fo
r dr
ug e
xpos
ure
Brea
st46
872
Nev
er1.
0A
ttai
ned
age,
cal
enda
r-ye
ar
Ass
ocia
tion
foun
d on
ly w
ith c
urre
nt u
se
of d
igox
in a
nd st
rong
er w
hen
rest
rict
ed
to w
omen
with
ER-
posit
ive
tum
ours
. D
urat
ion
resu
lts a
pply
to a
ll br
east
ca
ncer
s, re
gard
less
of E
R st
atus
.
2144
Ever
1.24
(1.18
–1.3
0)45
4Fo
rmer
0.91
(0.8
3–1.
00)
1690
Cur
rent
1.39
(1.3
2–1.
46)
IARC MONOGRAPHS – 108
398
Ref
eren
ce,
loca
tion
, and
pe
riod
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
Expo
sed
case
sEx
posu
re
cate
gory
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
for p
oten
tial
con
foun
ders
C
omm
ents
Bigg
ar e
t al.
(201
1),
Den
mar
k,
1995
–200
8(c
ont.)
Dur
atio
n of
us
e in
new
us
ers o
nly
(mo)
:30
60–
121.
65 (1
.47–
1.86
)14
713
–24
1.31
(1.1
2–1.
55)
9225
–36
1.13
(0.9
2–1.
38)
265
37+
1.31
(1.16
–1.4
8)ER
, est
roge
n re
cept
or; m
o, m
onth
; ref
., re
fere
nce;
vs,
vers
us; y
r, ye
ar
Tabl
e 2.
2 (
cont
inue
d)
Digoxin
399
among current users. Patterns of risk with dura-tion of digoxin use were not consistent by cancer type. For cancer of the uterus, stronger asso-ciations were observed for digoxin use of 0–12 months (RR, 1.60; 95% CI, 1.23–2.07) and > 37 months (RR, 1.91; 95% CI, 1.51–2.41) among current users, while for cancer of the ovary the strongest association was for digoxin use of 0–12 months among current users (RR, 1.37; 95% CI, 1.01–1.86) among current users. [The strengths and limitations of this study were the same as for the study of cancer of the breast based on the same cohort (Biggar et al., 2011).]
2.3 Cancer of the prostate
Cohort studies
See Table 2.4Platz et al. (2011) examined the association
between incidence of cancer of the prostate and use of digoxin in the USA-based Health Professionals Follow-up Study, following 47 884 men from 1986 until 2006. Data on use of digoxin were obtained by self-administered question-naire at baseline and at 2-year intervals during follow-up. Ever-users of digoxin had lower inci-dence of cancer of the prostate compared with never-users, after adjustment for multiple risk factors, including race, body mass index, exer-cise, and smoking (RR, 0.83; 95% CI, 0.72–0.94), which was not changed by adjustment for other cardiovascular drugs (cholesterol-lowering agents, aspirin). The inverse association was seen regardless of indication for digoxin use (heart failure or arrhythmia), present when digoxin was the only cardiac medication used (other than aspirin), apparent at all stages of cancer of the prostate, and stronger in current than former users. The adjusted risk ratio for cancer of the prostate decreased with duration of use from 0.87 (0.73–1.04) for those with < 5 years of use to 0.54 (0.37–0.79) for those with ≥ 10 years of use (P for trend < 0.001). [This was regarded as a
high-quality study with robust findings adjusted for an extensive array of covariates. Although exposure data were self-reported, reports by the health professionals were assumed to be of rela-tively high quality. Cancer outcomes were also self-reported, but validated by pathology-record review in 95% of cases.]
The association between cancer of the pros-tate and ever-use of drugs in the digitalis group was examined in the cohort study by Friedman & Ury (1980) and Friedman (1984), described in Section 2.1.2. The standardized morbidity ratio was 1.4 [95% CI, 1.00–2.01; 34 cases].
An increased risk of cancer of the prostate was also reported in the Norwegian cohort study by Haux et al., (2001). The relative risk was 1.25 (95% CI, 1.03–1.50). [As noted in Section 2.1.2, relative risks were elevated for most of the cancers exam-ined, leading to doubts about the appropriateness of the comparison group.]
2.4 Non-Hodgkin lymphoma
Case–control study
See Table 2.5To determine whether the development of
non-Hodgkin lymphoma is associated with medication use, Bernstein & Ross (1992) reviewed prescription-medication use in 619 cases of non-Hodgkin lymphoma in Los Angeles, USA, between 1979 and 1982, that were matched to 619 age, race, sex, and neighbourhood controls. Among 49 medications evaluated (along with many other health conditions and immuniza-tions), the odds ratios for use of digitalis were 1.55 (95% CI, 0.99–2.43) for men and women combined, 2.4 (95% CI, 1.31–4.38) for women and 0.75 (95% CI, 0.36–1.59) for men. A trend with duration of use was found in women, but not in men. [Multiple comparisons were made with many drug- and non-drug-related varia-bles, and the association with digitalis, seen only
IARC MONOGRAPHS – 108
400
Tabl
e 2.
3 Co
hort
stu
dy o
n us
e of
dig
oxin
and
can
cer o
f the
cor
pus
uter
i, ce
rvix
, and
ova
ry
Ref
eren
ce,
loca
tion
, an
d pe
riod
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
sEx
pose
d ca
ses
Expo
sure
ca
tego
ries
Rel
ativ
e ri
sk (9
5%
CI)
Adj
ustm
ents
for p
oten
tial
con
foun
ders
C
omm
ents
Bigg
ar et
al.
(201
2), D
enm
ark,
19
95–2
008
See
Tabl
e 2.
2 an
d B
igga
r et
al.
(201
1)
Nat
ionw
ide
phar
mac
y re
gist
ry
Cor
pus u
teri
111
Form
er1.
20 (0
.99–
1.45
)A
ttai
ned
age,
cal
enda
r yea
r A
ssoc
iatio
n to
dig
oxin
foun
d on
ly fo
r ute
rine
ca
ncer
and
stat
istic
ally
sign
ifica
nt o
nly
in
curr
ent u
sers
; mar
gina
l ass
ocia
tion
for f
orm
er
user
s. Fo
r ute
rine
can
cer,
incr
ease
gre
ates
t with
pr
olon
ged
use;
Fo
r all,
a h
ighe
r inc
iden
ce w
as n
oted
in th
e fir
st y
ear a
fter d
iagn
osis
, whi
ch c
ould
sugg
est
conf
ound
ing
by in
dica
tion
350
Cur
rent
1.48
(1.3
2–1.
65)
D
urat
ion
of u
se
(mo)
:
590–
121.
60 (1
.23–
2.07
)26
13–2
41.
19 (0
.81–
1.75
)11
25–3
60.
70 (0
.39–
1.27
)71
37+
1.91
(1.5
1–2.
41)
Ova
ry70
Form
er0.
95 (0
.75–
1.21
)20
7C
urre
nt1.
06 (0
.92–
1.22
)D
urat
ion
of u
se
(mo)
:42
0–12
1.37
(1.0
1–1.
86)
2013
–24
1.11
(0.7
1–1.
72)
1325
–36
1.01
(0.5
8–1.
74)
3037
+1.
02 (0
.71–
1.46
)C
ervi
x ut
eri
36Fo
rmer
1.18
(0.8
5–1.
65)
81C
urre
nt1.
00 (0
.79–
1.25
)D
urat
ion
of u
se
(mo)
:18
0–12
1.44
(0.9
1–2.
30)
813
–24
1.10
(0.5
5–2.
20)
525
–36
0.96
(0.4
0–2.
31)
837
+0.
66 (0
.33–
1.32
)
mo,
mon
th
Digoxin
401
Tabl
e 2.
4 Co
hort
stu
dy o
n us
e of
dig
oxin
and
can
cer o
f the
pro
stat
e
Ref
eren
ce,
loca
tion
, an
d pe
riod
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
sEx
pose
d ca
ses
Expo
sure
ca
tego
ries
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
for p
oten
tial
co
nfou
nder
s C
omm
ents
Plat
z et
al.
(201
1),
Hea
lth P
rofe
ssio
nals
Follo
w-u
p St
udy,
USA
, 19
85–2
006
Men
age
d 40
–75
year
s (n
= 47
884
)
Self-
repo
rted
qu
estio
nnai
re d
ata
abou
t cu
rren
t use
of d
igox
in
Pros
tate
, in
vasiv
e ca
ncer
4923
Nev
er1.
0A
ge, r
ace,
cal
enda
r yea
r, BM
I, he
ight
, sm
okin
g,
diab
etes
, die
t, ex
erci
se,
vita
min
E su
pple
men
t C
ohor
t ana
lysi
s und
erta
ken
to a
sses
s effe
cts o
bser
ved
in
vitr
o (s
ee S
ectio
n 4)
. C
ance
r sel
f-rep
ort
supp
lem
ente
d w
ith d
eath
-ce
rtifi
cate
dat
a; p
atho
logy
-re
cord
revi
ew: 9
4.5%
co
mpl
ete.
243
Ever
0.83
(0.7
2–0.
94)
175
Cur
rent
0.78
(0.6
7–0.
90)
D
urat
ion
of
use
(yr)
:
N
ever
1.0
125
< 5
0.87
(0.7
3–1.
04)
905–
9.9
0.87
(0.7
0–1.
07)
28≥
100.
54 (0
.37–
0.79
)
BMI,
body
mas
s ind
ex; y
r, ye
ar
IARC MONOGRAPHS – 108
402
Tabl
e 2.
5 Ca
se–c
ontr
ol s
tudy
on
use
of d
igit
alis
and
non
-Hod
gkin
lym
phom
a
Ref
eren
ce,
loca
tion
, an
d pe
riod
Subj
ects
Expo
sure
as
sess
men
tO
rgan
site
sEx
posu
re c
ateg
orie
sEx
pose
d ca
ses
Rel
ativ
e ri
sk
(95%
CI)
Adj
ustm
ents
for
pote
ntia
l co
nfou
nder
s
Bern
stei
n &
Ros
s (1
992)
, Lo
s Ang
eles
C
ount
y (U
SA),
1979
–82
Cas
es, 6
19
Con
trol
s, 61
9 (n
eigh
bour
hood
)
Pers
onal
inte
rvie
w
and
ques
tionn
aire
in
clud
ing
ever
-use
of
“dig
italis
”
Non
-Hod
gkin
ly
mph
oma
No
digi
talis
351.
00M
atch
ed o
n ag
e,
sex,
race
, and
ne
ighb
ourh
ood
Dig
italis
(all)
521.
55 (0
.99–
2.43
)M
en12
0.75
(0.3
6–1.
59)
Wom
en40
2.40
(1.3
1–4.
38)
All
(men
and
wom
en)
No
digi
talis
1.
00
D
igita
lis 1
–12
mo
231.
35 (0
.99–
2.43
)
D
igita
lis ≥
13
mo
281.
68 (0
.92–
3.08
)
P
for t
rend
0.
063
Men
No
digi
talis
1.
00
D
igita
lis 1
–12
mo
71.
00 (0
.35–
2.85
)
D
igita
lis ≥
13
mo
0.
56 (0
.19–
1.66
)
P
for t
rend
0.
34
W
omen
No
digi
talis
1.
00
Dig
italis
1–1
2 m
o16
1.72
(0.7
6–3.
91)
Dig
italis
≥ 1
3 m
o23
3.05
(1.3
5–6.
87)
P fo
r tre
nd
0.04
2
mo,
mon
th
Digoxin
403
in women and not in men, could have been a chance finding.]
2.5 Other cancer sites
See Table 2.2Elevated relative risks of cancers of the lung
and colorectum were observed in the cohort study by Friedman & Ury (1980) and Friedman (1984), and in the cohort study by Haux et al. (2001) described in Section 2.1.2. The relative risk of cancer of the lung was 1.7 [95% CI, 1.22–2.20] in the former study, and 1.35 (95% CI, 1.04–1.74) in the latter. For cancer of the colorectum, the relative risks were 1.5 [95% CI, 1.02–2.04] and 1.29 (95% CI, 1.06–1.51) for the same studies, respectively. Haux et al. (2001) also reported an increased risk of leukaemia and lymphoma combined (RR. 1.41; 95% CI, 1.06–1.85). [The Working Group considered that the study by Haux et al. (2001) may have used an inappro-priate comparison group, as noted in Section 2.1.2, and had limited confidence in the results. The elevated relative risk of cancer of the lung could be due to an association between smoking and cardiovascular disease for which digitalis was prescribed.]
3. Cancer in Experimental Animals
No data were available to the Working Group.
4. Mechanistic and Other Relevant Data
4.1 Absorption, distribution, metabolism, and excretion
4.1.1 Humans
(a) Absorption and distribution
Digoxin exhibits first-order kinetics (Ehle et al., 2011). In six healthy volunteers (average age, 20 ± 2.5 years) given a single infusion of digoxin of 750 µg for 20 minutes (Finch et al., 1984), digoxin had a half-life of 37.2 ± 12 hours, an area under the curve (AUC) of concentra-tion–time of 147.7 ± 78.6 ng/mL per hour, a large volume of distribution (311.4 ± 94.0 L) and clear-ance rate of 108.6 ± 59.1 mL/minute. In a study in four healthy men given 1 mg of tritium-labelled digoxin by intravenous injection (Marcus et al., 1964), the drug disappeared very rapidly from the circulation; 3 minutes and 1 hour after the injec-tion, only 15.9% and 2.8%, of the administered dose, respectively, was detected in the blood. The onset of pharmacological action, after intrave-nous administration, is detected within 15–30 minutes, and maximum effect within 1–4 hours (Ehle et al., 2011).
The distribution of digoxin follows a two-compartment model (Reuning et al., 1973), comprising plasma and rapidly equilibrating tissues (compartment one [small volume]), and the more slowly equilibrating tissues (compart-ment two [large volume]) (Currie et al., 2011). Equilibrium between compartments is achieved after a minimum of 6 hours, distribution half-life is 35 minutes, onset of action (oral) approximately 30–120 minutes, and time to peak action (oral) is 6–8 hours (Currie et al., 2011), or 2–6 hours, as reported by Ehle et al. (2011). Digoxin is 20–25% bound to plasma proteins (Ehle et al., 2011).
After oral administration of digoxin, half-life and time to steady state vary significantly
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between individuals, and are also dependent on renal function (Ehle et al., 2011). In healthy subjects, the half-life is 1.5–2 days (Currie et al., 2011; Ehle et al., 2011), and steady state is reached in 5–7 days (Ehle et al., 2011). In anuric patients, half-life is prolonged to 3.5–5 days (Currie et al., 2011; Ehle et al., 2011), and steady state is reached in up to 15–20 days (Ehle et al., 2011). The volume of distribution is 4–7 L/kg in healthy subjects (Ehle et al., 2011), but is decreased in people with renal disease and hypothyroidism, and increased in people with hyperthyroidism (Currie et al., 2011). A study of 32 men and 35 women receiving long-term therapy with digoxin (in doses indi-vidualized according to body weight), showed no sex-based differences in serum concentration of digoxin (Lee & Chan 2006).
Oral bioavailability (F) of digoxin varies with formulation, and between individuals. Bioavailability from digoxin capsules, elixirs, or tablets are 90%, 80%, and 70%, respectively (Ehle et al., 2011), and almost 100% from gela-tine capsules (Currie et al., 2011). Bioavailability of digoxin is physiologically controlled by the transmembrane transporter, P-glycoprotein, which has efflux pump function (Riganti et al., 2011). P-glycoprotein controls bioavail-ability from its location on apical (or luminal) membranes of enterocytes of the small intestine, by active extrusion of digoxin, back into the lumen of gastrointestinal tract. A critical factor in intestinal absorption is the rate of apical efflux (Riganti et al., 2011).
(i) Studies supporting an effect of MDR1 polymorphism
A study in 21 Caucasian individuals given a single oral dose of digoxin of 0.25 mg showed a correlation between polymorphism of the MDR1 gene [the gene encoding P-glycoprotein, standard nomenclature, ABCB1] at exon 26 (C3435T) and significantly lower levels of duodenal expression and function of MDR1. Polymorphic individuals had higher plasma concentrations of digoxin
compared with those with wildtype (C3435C) alleles (Hoffmeyer et al., 2000).
In eight volunteers, pre-treatment with rifampicin, an inducer of P-glycoprotein, altered absorption of digoxin. The rifampicin-induced mean concentration of digoxin in people carrying the T-allele single-nucleotide polymorphism was higher than that of the wildtype (CC) population (Hoffmeyer et al., 2000).
In healthy volunteers (with the TT and CC genotypes [n = 7 in each group]) given multiple oral doses of digoxin (0.25 mg per day) to achieve steady-state conditions, a statistically significant difference (mean, 38%) was found in maximum serum concentration of digoxin (Cmax) between the two groups [read from Figure: CC, ~1.60 µg/L; TT, ~2.15 µg/L]. This may reflect the importance of genotype in determining absorption after oral administration of digoxin (Hoffmeyer et al., 2000).
In 24 healthy Caucasian men who were homozygous carriers of the wildtype exon 26 C3435T (CC), or heterozygous (CT), or homozy-gous mutant (TT) [n = 8 in each group], AUC0–4h (P = 0.042) and Cmax (P = 0.043) differed signif-icantly, with higher serum concentrations of digoxin in men with the 3435TT genotype than in those with wildtype C3435T (CC). No influ-ence on digoxin parameters was detected for other single-nucleotide polymorphisms (Johne et al., 2002).
Genotypes deduced from single-nucleotide polymorphism 2677G-T (exon 21) and 3435C-T, substantiated by haplotype analysis, also showed significant differences in AUC0–4h and Cmax. These analyses indicated that haplotype 12 (2677G/3435T) was associated with high values of AUC0–4h and Cmax for orally administered digoxin (Johne et al., 2002).
In homozygous carriers of TT, kinetic param-eters indicated a faster and more complete absorp-tion of digoxin than in carriers of the wildtype. The digoxin plasma time course was evidenced by a 24% higher Cmax and by a 22% higher AUC0–4h,
Digoxin
405
considered to result from increased rate (indi-cated by the steeper ascending phase of the curve in TT individuals) and extent of absorption (and not primarily of distribution) (Johne et al., 2002).
High doses of digoxin are thought to satu-rate P-glycoprotein transport, triggering addi-tional mechanisms. Thus, it is likely that at low doses, the pharmacokinetics of digoxin will be influenced by P-glycoprotein transport only, and thus would be more greatly perturbed by genetic differences in P-glycoprotein activity (Johne et al., 2002).
A study of elderly patients in the Netherlands (n = 195; mean age, 79.4 years) who were taking digoxin regularly also showed that the common MDR1 variants, 1236C-T, 2677G-T, and 3435C-T and the associated TTT haplotype were corre-lated with higher serum concentrations of digoxin (Aarnoudse et al., 2008).
To understand the relative contribution of environmental and genetic factors to the phar-macokinetic variability of oral and intravenous digoxin, Birkenfeld et al. (2009) conducted a pilot study in 11 pairs of monozygotic twins (whose genes are almost identical), and 4 pairs of dizy-gotic twins (control). Measures of peak plasma concentration and Tmax of digoxin, and calcu-lated AUC, bioavailability, and renal clearance, after oral or intravenous administration, demon-strated strong correlation between monozygotic twins, findings explained largely by inheritance of P-glycoprotein function (Birkenfeld et al., 2009).
(ii) Studies not supporting an effect of MDR1 polymorphism
Other studies have not shown an association between polymorphism in the MDR1 gene and increased plasma concentrations of digoxin. A study in 114 healthy Japanese people given a single oral dose of digoxin of 0.25 mg (Sakaeda et al., 2001) showed the serum concentration to be lower in those with a mutant allele (C3435T) at exon 26 of the MDR1 gene. For the wildtype
allele (CC), heterozygotes with a mutant T allele (C3435T) (CT), and homozygotes for the mutant allele (TT), values for AUC0–4h (± standard deviation) were 4.11 ± 0.57, 3.20 ± 0.49, and 3.27 ± 0.58 ng/hour per mL, respectively. There was a significant difference between CC and CT or TT.
In a study in 39 Caucasian patients with congestive heart failure given digoxin at 0.25 mg per day for at least 7 days to reach steady state, Kurzawski et al. (2007) evaluated the effects of MDR1 gene polymorphism on serum concentra-tions of digoxin, and in 24 patients, the effects of coadministration of digoxin with P-glycoprotein inhibitors. Significantly higher (approximately 1.5-fold) (P < 0.002) minimum serum concentra-tions of digoxin at steady state (Cmin ss) were shown in patients given inhibitors of P-glycoprotein (0.868 ± 0.348 ng/mL), compared with those not given inhibitors (0.524 ± 0.281 ng/mL); however, in contrast to other studies, no association was found between 3435C > T and 2677G > A,T MDR1 single-nucleotide polymorphisms and steady-state serum concentrations of digoxin (Kurzawski et al., 2007).
A higher (1 mg) single oral dose of digoxin, without drug pre-treatment, in 50 healthy white men (aged 18–40 years) showed no differences in the AUC0–4h, Cmax, or tmax (as indices of digoxin absorption) among the genotype groups tested (Gerloff et al., 2002). In contrast to previous reports (Hoffmeyer et al., 2000), no differences were seen between homozygous carriers of the C and T allele in exon 26 3435 (AUC0–4h, 9.24 and 9.38 mg/hour; Cmax, 4.73 and 3.81 µg/L; tmax, 0.83 and 1.14 hours, respectively). The MDR1 single-nucleotide poly-morphisms studied, including that in exon 26, did not affect the absorption of a single oral dose of 1 mg of digoxin, and it was suggested that the higher dose (1 mg) of digoxin may have caused saturation of the transport capacity of intestinal P-glycoprotein. The pharmacokinetics of digoxin showed substantial variation within each geno-typic group, indicating that factors additional to
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P-glycoprotein may influence the absorption of digoxin (Gerloff et al., 2002).
It is likely that passive diffusion (Gerloff et al., 2002) or other transporters (Johne et al., 2002), in addition to P-glycoprotein, contribute to variations in the pharmacokinetics of digoxin. Digoxin is a substrate for OATP8 (a member of the organic anion-transporting polypeptide group), for which genetic variants have been identified (Johne et al., 2002), the effects of which, have not yet been elucidated. In addi-tion, genetic variation in regulatory proteins, for example, the pregnane X receptor, involved in regulation of P-glycoprotein, may also affect digoxin disposition (Birkenfeld et al., 2009). The absorption of digoxin may also be influenced by environmental factors (such as diet) by induction or inhibition of P-glycoprotein activity (Johne et al., 2002; Gerloff et al., 2002), or by genetic variants governing its distribution and elimina-tion (Gerloff et al., 2002).
(b) Metabolism
Gault et al. (1984) demonstrated a major metabolic sequence of digoxin hydrolysis, oxida-tion, and conjugation, leading to polar end-me-tabolites. In this study, 10 patients with end-stage renal failure (who were dependent on dialysis), and 5 patients with comparatively normal renal function were given digoxin (as an oral dose of 150 μCi of [3H]digoxin-12α) and the metabolites were analysed by high-performance liquid chro-matography (HPLC). Of these patients, 13 were receiving maintenance therapy with digoxin and were at steady state. The extent and time course of metabolism of digoxin varied between subjects, but variation was not significant between the two groups with different renal function. For all 15 patients, at 6 hours after drug administration, 26% (range, 7–76%) of the radiolabel was in the form of polar metabolites (quantitatively the most abundant metabolites), and 60% (range, 11–88%) was unchanged digoxin. Metabolites usually found albeit in small amounts were
3β-digoxigenin and its mono- and bis-digitoxo-sides, and 3-keto and 3α(epi)-digoxigenin.
This metabolic route comprised initial hydrolysis to 3β-digoxigenin with release of sugars in the stomach or liver, followed rapidly by oxidation to 3-keto-digoxigenin, epimerization to 3α(epi)-digoxigenin and finally glucuronide conjugation to polar species, 3-epi-glucuronide and 3-epi-sulfate. Results also indicated that conjugation of the mono-digitoxoside may occur, with steroid-ring hydroxylation, producing two isomers. In individuals demonstrating extensive metabolism, the lactone ring may be opened (possibly by a lactonase), forming a highly polar metabolite, or reduced, forming dihydro-metab-olites (Gault et al., 1984).
In studies using suspensions of freshly isolated human hepatocytes in vitro, metabolism of [3H]digoxin-12α has been shown to be very low (Lacarelle et al., 1991); after a 2-hour incuba-tion, extracellular radiolabel represented largely unchanged digoxin (up to 93%), with a minor (5% of the total extracellular radiolabel) unidentified polar metabolite. Similar results were obtained over a 24-hour exposure time in cultured human hepatocytes, and also in human liver microsomal fractions, indicating that cleavage of digoxin sugars is not dependent on the cytochrome P450 (CYP) system that requires reduced nicotina-mide adenine dinucleotide phosphate (NADPH) (Lacarelle et al., 1991; also see Fig. 4.1).
Digoxigenin mono-digitoxoside was exten-sively metabolized by human cultured hepato-cytes to a single, more polar metabolite, which was subsequently completely hydrolysed by β-D-glucuronidase, and thus identified as the glucuronide of digoxigenin mono-digitoxoside. The extent of glucuronidation analysed in human liver microsomal fractions prepared from 13 different subjects was shown to vary among indi-viduals by a factor of 3 (Lacarelle et al., 1991).
Digoxigenin was also extensively biotrans-formed by cultured human hepatocytes. HPLC peaks were shown for one or more glucuronides,
Digoxin
407
3-epi-digoxigenin, unchanged digoxigenin, and possibly for unidentified metabolites. The intracellular concentration of 3-epi-digoxigenin decreased, due to conversion to polar compounds, which effluxed from the cells as formed. In human liver microsomes, no metabolites were observed in the absence of cofactor (NADPH or uridine 5′-diphospho-glucuronic acid, UDPGA); however, with NADPH present, “pre-digoxi-genin” was detected. Formation of “pre-digoxi-genin” therefore appeared to be CYP-dependent, with a large variability observed among individ-uals (Lacarelle et al., 1991; also see Fig. 4.1).
In contrast, formation of 3-epi-digoxigenin did not depend on microsomal enzymes; it was only observed after incubation of digoxigenin with hepatocytes, and not with microsomes. In the presence of both NADPH and UDPGA, only small quantities of polar compounds were observed. These findings confirmed that 3-epi-di-goxigenin is formed before synthesis of polar compounds. Thus, the main metabolic route for digoxigenin in vitro is the formation of 3-epi-di-goxigenin, which is conjugated to a glucuronide (Lacarelle et al., 1991; also see Fig. 4.1).
(c) Elimination
Recovery of digoxin in the urine was reported as 70–85% (Currie et al., 2011) and 50–70% (Ehle et al., 2011). Drug recovery in the faeces was, on average, 14.8% of the administered dose, of which 14% comprised metabolic products (Marcus et al., 1964).
In a study of the mechanisms of intestinal and biliary transport of digoxin, eight healthy men (aged 21–37 years), were given segmental intestinal perfusion of a P-glycoprotein inhibitor (quinidine) or inducer (rifampin), with intrave-nous administration of digoxin (1 mg). Results showed that intestinal P-glycoprotein mediates the elimination of intravenously administered digoxin from the systemic circulation into the gut lumen, as well as the control of absorp-tion of orally administered digoxin from the
gastrointestinal tract. These data also demon-strated a non-renal mechanism of elimination of digoxin, entailing direct secretion into the small intestine from the systemic circulation, which had greater importance than elimination via bile (Drescher et al., 2003).
The organic anion transporter in human kidney (OATP4C1) may have an initial role in the transport of digoxin to the kidney. These transporters have been isolated, and shown by immunohistochemical analysis to be localized at the basolateral membrane of the proximal tubule cell in the kidney. Both human OATP4C1 and rat OATP4C1 transport digoxin in a sodium-inde-pendent manner (Mikkaichi et al., 2004).
The role of OATPs in the disposition of digoxin has not been clearly defined. Data from various in-vitro systems have indicated that digoxin is not a substrate for human OATP1A2, OATP1B1, OATP1B3, or OATP2B1, although OATP4C1 may facilitate active uptake of digoxin into human kidney and liver. Digoxin is a substrate for a sodium-dependent transporter, shown to be endogenously expressed in a human kidney cell line (HEK29), and may, by its location in proximal tubular cells, partially facilitate renal clearance of digoxin (Taub et al., 2011).
(d) Interactions
The bioavailability of digoxin is affected by concurrent administration of many drugs which compete for binding to P-glycoprotein. Thus, digoxin auto-regulates its absorption. Many lipophilic P-glycoprotein-inducing drugs also promote CYP3A activity, and so a complex, and poorly understood, network of interactions between drugs or endogenous metabolites may affect transport and metabolic inactivation of digoxin (Riganti et al., 2011).
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Fig. 4.1 Structure of digoxin and proposed metabolic pathways
Digitoxoses Digoxigenin
Digoxin (DG3) Dihydrodigoxin
Dihydrodigoxigenin
Digoxigeninbis-digitoxoside
(DG2) (two sugars)
Digoxigeninmono-digitoxoside (DG1) (one sugar)
Digoxigenin (DGO)(no sugar)
Epidigoxigenin Conjugates(glucuronides, sulfates)
Stepwise cleavage ofthe digitoxoses
Reduction of
the lactone
OH3C
OHO
HO
OO
H3C
HO
OH3C
O
HO
OH
H
OH
CH3
H
H3C
H
O O
Unknown polar compounds
?
From Lacarelle et al. (1991), Copyright © 1991, John Wiley and Sons
Digoxin
409
4.1.2 Experimental systems
(a) Absorption
The pharmacokinetics of digoxin was studied in male Sprague-Dawley rats given an intrave-nous bolus dose at 1 mg/kg bw. Plasma and urine samples were analysed by thin-layer chromatography to separate digoxin and its metabolites. Digoxin concentrations were described as a two-com-partment model. Parent drug was rapidly elimi-nated from the plasma, with half-life of 2.5 hours, a volume of distribution of 3.6 L/kg, and a total body clearance of 5.77 mL/minute. Bile-duct ligation produced comparable pharmacokinetic parameters (with the exception of the total body clearance, 5.18 mL/minute). In rats with bilateral ureter ligation, the plasma half-life of digoxin was increased to 4 hours (Harrison & Gibaldi, 1976).
The function of P-glycoprotein in vivo has been investigated pharmacokinetically, using mdr1a (−/−) mice [Abcb1a (−/−)] (Schinkel et al., 1995; Mayer et al., 1996; Kawahara et al., 1999). These mice show no major pathology, but their intestinal epithelium and brain endothelial cells have no detectable P-glycoprotein (Schinkel et al. 1995). Schinkel et al. (1995) demonstrated that concentrations of [3H]digoxin in plasma and most tissues were twofold, and in brain were 35-fold, in mdr1a (−/−) mice given [3H]digoxin intravenously compared with mdr1a (+/+) mice. Similarly, Kawahara et al. (1999) reported that digoxin accumulation in the brain was 68-fold higher. Mayer et al. (1996) further demonstrated that the brain concentrations of [3H]digoxin continued to increase over 3 days after injec-tion in mdr1a (−/−) mice, resulting in a 200-fold higher concentration than in mdr1a (+/+) mice. However, Kawahara et al. (1999) reported that disruption of the mdr1a gene did not to change plasma-protein binding or the blood-to-plasma partition coefficient.
Inhibition studies in vitro have shown that anionic transporters, in addition to
P-glycoproteins, are involved in the absorption of digoxin (Yao & Chiou, 2006).
An additional non-MDR1 component may contribute to active secretion of digoxin back into the lumen, to limit its intestinal absorption. In support of this, MDR1-transfected Madin-Darby canine kidney (MDCKII) cell monolayers showed reduced secretion of digoxin by the MDR1 inhibitor cyclosporin A, but not by the MDR1 inhibitor MK-571 (Lowes et al., 2003).
(b) Metabolism
A proposed metabolic pathway for digoxin is shown in Fig. 4.1 (Lacarelle et al., 1991).
In humans, more than 73% of an intravenous dose is excreted unchanged via the kidneys. In contrast, the rat metabolizes approximately 60% of an intraperitoneal dose, and approximately 30% is excreted via biliary and urinary routes (Harrison & Gibaldi, 1976).
Metabolism of digoxin follows a similar metabolic pathway in humans and rats, i.e. step-wise cleavage of the sugar residues to form the digoxigenin bis- and mono-digitoxoside and the aglycone digoxigenin before conjugation and elimination, but the rate is faster in rats (Harrison & Gibaldi, 1976).
The three sequential steps of oxidative metab-olism of digoxin (to digoxigenin bis-digitoxoside, digoxigenin mono-digitoxoside, and digoxigenin) were studied in rat liver microsomes (Salphati & Benet, 1999). Inhibition of the CYP3A subfamily with ketoconazole or triacetyloleandomycin, or with antibodies specific to rat CYP3A2, affected oxidative metabolism; the formation of digoxigenin bis-digitoxoside and digoxigenin mono-digitoxoside decreased by up to 90%, and the rate of oxidation of digoxin and digoxi-genin bis-digitoxoside was decreased by up to 85%, respectively. These oxidation reactions were unaffected by chemical or immunological inhibition of CYP2E1, CYP2C or CYP1A2. The subsequent metabolic step, i.e. oxidation of digox-igenin mono-digitoxoside, was not inhibited
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by triacetyloleandomycin or by antibodies to CYP3A2, CYP2C11, CYP2E1, CYP2B1/2B2 or CYP1A2, but was however reduced (by > 80%) by inhibitors of human CYP3A. In summary, these results indicated that CYP3A, most likely CYP3A2, is the primary enzyme responsible for metabolism of digoxin and digoxigenin bis-digi-toxoside in rat liver microsomes, but the enzyme that metabolizes digoxigenin mono-digitoxoside remains to be identified (Salphati & Benet, 1999).
(c) Elimination
Digoxin is eliminated primarily via the kidney through glomerular filtration and tubular secretion. P-glycoprotein has a role in the elimi-nation of digoxin. Studies in vitro have demon-strated that mouse mdr1a and human MDR1 P-glycoprotein actively transport digoxin across a polarized kidney epithelial cell layer (Schinkel et al., 1995). Furthermore, experiments in vivo showed that mdr1a (−/−) mice eliminated [3H]digoxin-12α more slowly (Schinkel et al., 1995). The total body clearance was lower in mdr1a (−/−) mice than in the wildtype (+/+) mice; however, disruption of the mdr1a gene did not change the contributions of renal and bile clearances to total clearance (Kawahara et al., 1999).
Digoxin is partly excreted via the biliary system. In male Sprague-Dawley rats, total body clearance values for digoxin were 10% lower in rats with bile-duct ligation, and were reduced by a further 30% by bilateral ureter ligation. The approximately 60% of total body clearance unaffected by ligations of bile duct or ureter were considered due to biotransformation of digoxin. A main excretory route for digoxigenin bis-dig-itoxoside was shown to be biliary as indicated by high levels of this metabolite in plasma and urine of rats with ligated bile ducts (Harrison & Gibaldi, 1976).
Intestinal P-glycoprotein in mice has been shown to contribute to excretion of [3H]digoxin via the gastrointestinal epithelium. Mayer et al. (1996) demonstrated a shift in balance of
excretion in mdr1a (−/−) mice given [3H]digoxin (0.2 mg/kg bw) as a single intravenous or oral bolus, i.e. lower faecal elimination of [3H]digoxin. This was due to reduced drug excretion via intes-tinal epithelium, since biliary excretion was not decreased in mdr1a (−/−) mice, and suggested that other transporters could be involved in the biliary excretion of digoxin. Indeed, the capacity for renal excretion remained substantial, and cumulative urinary excretion of digoxin in mdr1a (−/−) mice was greater than in wildtype (+/+) mice. Thus, intestinal P-glycoprotein acts by directly excreting digoxin into the intestinal lumen, and also limiting the rate of its re-up-take from the intestine by biliary excretion, thus directing faecal excretion (Mayer et al., 1996). [P-glycoprotein seems to have important roles in elimination of digoxin from the systemic circula-tion, and also in decreasing intestinal re-uptake of digoxin after biliary excretion.]
4.2 Genetic and related effects
No data were available to the Working Group.
4.3 Other mechanistic data relevant to carcinogenicity
4.3.1 Effects on cell physiology
The physiological action of digoxin involves binding to and inhibition of the α-subunit of the Na+/K+ ATPase pump on the myocyte plasma membrane. This causes an increase in intracel-lular concentrations of sodium and calcium ions. Digoxin shares some structural homology with steroid hormones, suggesting functional similar-ities (Schussheim & Schussheim, 1998; Newman et al., 2008). There is evidence that digitoxin at concentrations of 0.5–2.0 × 10−6 M competes with estrogen for the estrogen cytosolic receptor in the rat uterus; however, no evidence for competition by digoxin was obtained (Rifka et al., 1976; Rifka et al. 1978).
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411
Other intriguing evidence for digoxin includes a case report of gynaecomastia (Aiman et al., 2009), an increased relative risk of uraemic cancer in digoxin users (RR, 1.48; 45% CI: 1.32–1.65; n = 350) (Biggar, 2012), and lower relative risks of cancer of the prostate (RR, 0.76; 95% CI, 0.61–0.95) among regular users versus non-users (Platz et al., 2011).
4.3.2 Effects on cell function
Digoxin reduces synthesis of the TP53 protein in human cancer cell lines; this appears to be triggered by activation of Src/mitogen-acti-vated protein kinase signalling as a consequence of inhibition of the Na+/K+ ATPase pump (Wang et al., 2009). Digoxin also inhibits the action of cellular DNA topoisomerases in MCF-7 cells (Bielawski et al., 2006), and inhibits synthesis of hypoxia-inducible factor 1α (HIF-1α) in human Hep3B-c1 hepatoblastoma cells (Zhang et al., 2008). Digoxin may inhibit synthesis of steroids (Kau et al., 2005).
4.4 Susceptibility
4.4.1 Effects of age on elimination
Since young children require higher doses of digoxin per kilogram of body weight than adults to achieve pharmacological effects, there has been interest in whether expression of P-glycoprotein is age-dependent. Pinto et al. (2005) have studied mdr1a and mdr1b and the clearance rates of digoxin (dose, 7 μg/kg bw) in FVB mice of different ages (at birth, and age 7, 14, 21, 28 or 45 days). At birth and day 7, gene expres-sion of mdr1a and mdr1b was very low, but mdr1b levels were significantly higher at day 21 than at days 14 or 28. Digoxin clearance rates correlated significantly with expression of P-glycoprotein, showing highest clearance values at day 21. It was concluded that increases in digoxin clearance rates after weaning may be attributed, at least
in part, to similar increases in P-glycoprotein expression (Pinto et al., 2005).
Evans et al., (1990) showed that age affects the clearance of digoxin in rats. In male Fischer 344 rats (age, 4, 14, or 25 months) given [3H]digoxin and unlabelled digoxin at a dose of 1 mg/kg bw as an intravenous bolus dose, total body clear-ance was 14.2, 12.1, and 7.5 mL/minute per kg, respectively, indicating a significant decrease in clearance (P < 0.05). No difference was seen in the terminal elimination half-life (2.0, 2.3, and 2.5 hours respectively) or steady-state volume of distribution (1.51, 1.49, and 1.27 L/kg, respec-tively) in rats aged 4, 14, and 25 months. Serum protein binding did not change with age; the average percentage of unbound digoxin for all rats was 61.3 ± 5.3% (mean ± standard deviation; n = 15) (Evans et al., 1990).
4.4.2 Effects of renal failure on elimination
Tsujimoto et al. (2008) showed that, in contrast to normal serum, 10% uraemic serum inhibited the hepatic uptake of digoxin by human isolated hepatocytes (by 23%) and by rat hepatocytes (by 50%). It was further shown that the uraemic toxins 3-carboxy-4-methyl-5-propyl-2-furanpropanoic acid (CMPF), p-cresol, (both at 400 mM, which is within the plasma concentration range for patients with renal failure) and hippuric acid (at 3000 μM) significantly inhibited the uptake of digoxin. CMPF and p-cresol inhibited the uptake of digoxin into rat hepatocytes by 27% and 23%, respectively, and into human hepatocytes by 23% and 28%, respectively. These toxins were, however, not wholly responsible for inhibition of uptake. Indeed, 10% uraemic serum from patients contained these toxins at concentrations (CMPF, 37.6 mM; hippuric acid, 26.8 mM; and p-cresol, 19.5 mM) that may not have been sufficient to inhibit the uptake of digoxin. Additionally, the mechanism of inhibition of these toxins was competitive, while the inhibition shown by 10% uraemic serum was non-competitive. Thus, the
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inhibitory effects of 10% uraemic serum cannot be fully explained by the three major uraemic toxins studied (Tsujimoto et al., 2008).
4.5 Mechanistic considerations
The increase in the incidence of cancers of the breast and uterus after long-term treatment with digoxin (Biggar, 2012), and the observed estrogen-like side-effects of digoxin and digi-toxin (Rifka et al., 1976, 1978; Schussheim & Schussheim, 1998), suggested that digoxin and digitoxin act via estrogen-signalling pathways to increase cell proliferation in the mammary gland, potentially contributing to tumour devel-opment. However, mechanistic evidence was limited to a demonstration that digitoxin inhib-ited the binding of estradiol to specific, saturable binding sites in the rat uterine cytosol. Mammary epithelial cells contain several estrogen-binding proteins, including estrogen receptors (ERα and ERβ) and estrogen-related receptors (ERRα and ERRβ), and the signalling pathways linking receptor activation to cellular proliferation are complex (Gibson & Saunders, 2012). The molec-ular targets associated with the carcinogenic properties of digoxin and digitoxin have not yet been defined.
5. Summary of Data Reported
5.1 Exposure data
Digoxin is a glycoside isolated from Digitalis lanata and is used in the treatment of chronic heart failure and irregular heart rhythm. While use may have declined over the past 30 years, digoxin is still frequently prescribed. Global sales of digoxin were US$ 142 million in 2012, with 33% occurring in the USA. Other countries with appreciable use included Japan, Canada, and the United Kingdom.
Digitoxin, another glycoside isolated from D. purpurea, is used for the same indications as digoxin in certain countries; it is also found as an impurity in preparations of digoxin.
In most countries, use of “digitalis” would in practice almost always correspond to digoxin, unless digitoxin were specified.
Specifications for digitalis glycosides are provided in several international and national pharmacopoeia. In some countries, digoxin has been classified as a “hazard to water,” an “environmental hazard,” or as an “extremely hazardous substance.”
5.2 Human carcinogenicity data
Studies in humans have assessed the risk of cancer in patients who may have used digoxin, digitoxin, or digitalis drugs as a group. The prin-cipal cancer of interest is cancer of the breast. Although risk of some other cancers has been found to be increased, the literature on other cancers was insufficient to establish patterns of increased risk.
5.2.1 Cancer of the breast
Information about the association of cancer of the breast with use of digoxin and digitoxin is available from four case–control studies (including two studies in men) conducted in four Nordic countries, France, and Switzerland, and a nationwide cohort study of women in Denmark, and other cohort studies in the USA and Norway.
Statistically significant increases in the occur-rence of cancer of the breast in users of digoxin were seen in three case–control studies; in one study in women, the odds ratio was 1.3, while odds ratios were two- and fourfold in the two studies in men. The largest study, which included all women using digitalis in Denmark, reported an increased risk for current users (hazard ratio, 1.39). The positive associations with exposure to digoxin in this study were due to increased
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risk in current users only: there was no associ-ation in former users and the number of new tumours declined after discontinuing drug use. Dose–response effects were difficult to examine because of the narrow dose range, and trends in risk with duration of exposure were gener-ally not observed. In a case–case comparison among a subset of the same population, tumours occurring in digitalis users were reported to have more favourable prognostic features (estrogen receptor-positive) than in non-users. Data on the association of cancer of the breast with use of digitoxin were available from one cohort study in women in Denmark, which reported a positive association (relative risk, 1.39). These studies had limited ability to account for other risk factors for cancer of the breast, with obesity and alcohol drinking being of greatest concern.
5.2.2 Other cancer sites
Increases in the incidence of cancer of the uterus in current users of digoxin were found in one cohort study in Denmark. The same study found no increase in risk of cancers of the cervix and ovary. The risk of cancer of the prostate, another cancer that is influenced by hormones, was reduced in one high-quality cohort study from the USA, but increased in two others (one study with methodological weaknesses from Norway, and the other a very large data-base-screening programme from a health plan in northern California, USA). The increased risk of cancer of the uterus, and decreased risk of cancer of the prostate, is also consistent with a hormone-related mechanism, adding to the plausibility of the epidemiological findings.
Excess risks of cancers of the lung and colorectum were also observed in the cohort studies in Norway and northern California. The cohort study in Norway reported a posi-tive association with leukaemia and lymphoma combined.
In a case–control study from southern California, USA, a positive association was observed with non-Hodgkin lymphoma in women, but not in men.
5.2.3 Synthesis
Statistically significant associations of cancer of the breast with use of digoxin were observed consistently in women and men, across different geographical regions, and with different study designs. Cancer of the breast is rare in men and strengthens the validity of association observed for cancer of the breast in women. The record-linkage studies that provided key evidence were not able to adjust for many of the recognized risk factors for cancer of the breast, notably obesity and alcohol drinking, although there was no reason to believe these would be associated with use of digoxin. Although clear effects with duration and dose were not observed, a decline in the detection of new tumours after cessation of exposure was seen in the largest study from Denmark, consistent with a possible promoting effect of digoxin. The association was specific to estrogen receptor-positive tumours of the breast in the same study.
5.3 Animal carcinogenicity data
No data were available to the Working Group.
5.4 Mechanistic and other relevant data
Oral bioavailability of digoxin is generally high, but varies due to interindividual genetic differences in expression of the efflux pump, P-glycoprotein.
The metabolism of digoxin in rats and humans involves stepwise hydrolytic cleavage of the digi-toxoses to form digoxigenin bis- and mono-dig-itoxosides and the aglycone digoxigenin before conjugation and renal elimination.
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No data were available on genetic effects of digoxin or its metabolites.
Digoxin has structural homology with steroid hormones, suggesting functional simi-larities. The structurally related glycoside digi-toxin competes with estrogen for the rat uterine estrogen cytosolic receptor; however, no evidence for competition by digoxin was found.
Digoxin reduces synthesis of the TP53 protein in human cancer cells, inhibits cellular DNA topoisomerases, inhibits the synthesis of hypoxia- inducible factor 1α, and may inhibit synthesis of steroids.
The possible association between use of digoxin and an increased incidence of endo-crine-related human cancers (primarily breast) suggests a mechanism that is estrogen recep-tor-mediated. However, evidence that digoxin and digitoxin act through estrogen-signalling pathways was limited to a demonstration that digitoxin inhibited the binding of estradiol to specific, saturable binding sites in rat uterine cytosol. The molecular targets associated with the carcinogenic properties of digoxin and digi-toxin have not yet been identified.
6. Evaluation
6.1 Cancer in humans
There is limited evidence in humans for the carcinogenicity of digoxin. A positive association has been observed between use of digoxin and cancer of the breast.
6.2 Cancer in experimental animals
There is inadequate evidence in experimental animals for the carcinogenicity of digoxin.
6.3 Overall evaluation
Digoxin is possibly carcinogenic to humans (Group 2B).
The Working Group recognized a possible association between digoxin and an increased incidence of endocrine-related human cancers. However, the evidence that digoxin and digi-toxin act through an estrogen-receptor mediated mechanism was limited.
Favouring a Group 2A classification, the epidemiological data associating increased risk of cancer of the breast with use of digoxin were compelling. Consistent with an endocrine-medi-ated mechanism, the increase in risk was largely for estrogen receptor-positive tumours; further, risk of uterus cancer was increased and cancer of the prostate was decreased. The evidence in humans favoured a promoter effect that is seen only in current users.
Favouring a Group 2B classification, not all potential confounders were eliminated in the epidemiological studies, in particular, obesity. In addition, there were no available data from studies in experimental animals, and no known molecular mechanism by which digoxin might be a carcinogen. The weak evidence supporting an endocrine-mediated mechanism was noted as a problem.
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